User login
New treatments bring hope for severe atopic dermatitis
LOS ANGELES – For patients with severe atopic dermatitis and their families and treating physicians, there is big news: finally, there is light at the end of the tunnel, Dr. Lisa A. Beck declared in a plenary lecture at the annual meeting of the American Academy of Allergy, Asthma, and Immunology.
Better drugs are on the way. The new agents in the developmental pipeline target specific immunologic pathways that appear to be central to atopic dermatitis. Moreover, exciting recent evidence indicates it’s possible to noninvasively identify children at high risk for atopic dermatitis and intervene preventively to reduce the likelihood of actually developing the disease, according to Dr. Beck, professor of dermatology and medicine at the University of Rochester (N.Y.).
“Many pharmaceutical companies have now turned their attention to atopic dermatitis and aren’t just focusing on asthma anymore. The biggest pipeline appears to involve drugs that might target the Th2 [T helper 2 cells] pathway, either by trying to eliminate alarmins such as TSLP [thymic stromal lymphopoietin], or reverse the effects of the Th2 cytokines interleukin-4 and -13, either alone or together, or prevent the recruitment of activated T cells,” she said.
Dr. Beck presented an update on three such promising investigational approaches on the horizon: the IL-4 and IL-13 inhibitor dupilumab; oral and topical Janus associated kinase (JAK) inhibitors; and anti-IgE therapies.
Dupilumab: This fully human monoclonal antibody that blocks IL-4 and IL-13 is also being developed as a treatment for eosinophilic asthma. Dr. Beck was first author of a report on a series of four phase II randomized trials of dupilumab for moderate to severe atopic dermatitis in adults. The publication caused a stir, with dupilumab-treated patients showing marked and rapid improvement to a degree previously unseen in the treatment of this disease (N Engl J Med. 2014;371[2]:130-9).
In the 12-week study, for example, 85% of dupilumab-treated patients achieved at least a 50% improvement in the Eczema Area and Severity Index (EASI) score, compared with 35% of placebo-treated controls, with a significant between-group difference seen in the first week. Maximum improvement – a 75%-80% reduction in EASI scores – was noted at 6-8 weeks. Forty percent of dupilumab-treated patients achieved clear or near-clear skin by investigator’s global assessment, compared with just 7% of controls.
Itching decreased markedly beginning in the first week, too. The investigational agent’s side effect profile was similar to placebo. Phase III clinical trials in atopic dermatitis are ongoing.
A study by other investigators found that dupilumab resulted in rapid improvement in the molecular signature of atopic dermatitis in skin biopsy specimens (J Allergy Clin Immunol. 2014 Dec;134[6]:1293-300). The observed changes in gene expression suggest that dupilumab might have a beneficial effect on the dysfunctional skin barrier that is a hallmark of atopic dermatitis. Further studies are now being planned to take a closer look at that possibility.
JAK inhibitors: “We’re all really excited about this approach because dogs, too, get allergic dermatitis, and in 2013 a JAK 1 and 3 inhibitor [oclacitinib, Apoquel] was approved as a veterinary medicine therapy. It has resulted in dramatic improvement in itch within 1 week of administration, as well as significant improvement in the dermatitis,” Dr. Beck said.
Three JAK inhibitors are now in phase II clinical trials for atopic dermatitis in humans: the JAK 1 and 3 inhibitor tofacitinib (Xeljanz), both as a topical ointment and the familiar oral formulation; baricitinib, an oral JAK 1 and 2 inhibitor; and an agent known for now as PF-04965842, which is an oral inhibitor specifically of JAK 1.
“JAK inhibitors have been quite effective in treating a number of other inflammatory conditions, as well as cancers. I think they will have a role in the treatment of atopic dermatitis. The biggest concerns will be the off-target effects,” she predicted.
Anti-IgE agents: Omalizumab (Xolair), a humanized monoclonal antibody that binds to IgE, has gotten mixed reviews as an investigational treatment for atopic dermatitis. The best study to date, a randomized, single-center, placebo-controlled, double-blind, 16-week clinical trial, found that omalizumab depleted IgE but didn’t improve the clinical course of atopic dermatitis (J Dtsch Dermatol Ges. 2010 Dec;8[12]:990-8). Nonetheless, a phase II trial of omalizumab is ongoing. Plus, ligelizumab, an anti-IgE monoclonal antibody with a higher affinity for IgE than omalizumab, is also in a phase II trial for adult atopic dermatitis.
“Anti-IgE therapy, I think, is still not dead in atopic dermatitis. I look forward to seeing whether omalizumab will work in unique subsets of patients, or whether a more potent anti-IgE molecule will be more beneficial,” Dr. Beck commented.
As exciting as the prospects are for these investigational agents, there also have been several recent important advances in the prevention of atopic dermatitis, she continued. Investigators led by Dr. Alan D. Irvine of Trinity College, Dublin, noninvasively measured transepidermal water loss in early infancy in more than 1,900 Irish 2-day-old infants and found that those in the 75th percentile for this early marker of skin barrier dysfunction were at 3.1-fold increased risk for diagnosis of atopic dermatitis by age 2 years (J Allergy Clin Immunol. 2016 Apr;137[4]:1111-6). This new-found ability to identify at-risk infants will be extremely helpful in designing atopic dermatitis prevention studies, according to Dr. Beck.
The other advance in prevention was provided via a randomized trial by Dr. Eric L. Simpson of Oregon Health and Science University, Portland, and his coinvestigators. They randomized a group of infants at high risk for atopic dermatitis to daily application of any of five OTC skin moisturizers or a no-moisturizer control group from 2 weeks through 6 months of age. The study hypothesis was that the moisturizers would help reverse the skin barrier abnormalities that play a key role in atopic dermatitis. The hypothesis was borne out by the finding that there was at least a 50% reduction in physician-diagnosed atopic dermatitis by age 6 months in the daily moisturizer group (J Allergy Clin Immunol. 2014 Oct;134[4]:818-23).
Dr. Beck concluded by describing a likely near-term atopic dermatitis prevention and management scenario: High-risk infants will be identified on the basis of noninvasive assessment of epithelial features, such as transepidermal water loss or the presence of high levels of thymic stromal lymphopoietin on the skin surface. Encouragement of daily moisturizing for these high-risk infants will prevent some of them from going on to develop eczema.
For those who do get eczema, dilute bleach baths will help in restoring normal skin barrier function, as was confirmed in an in-press study by Dr. Beck and her coinvestigators, who found that 46% of a group of adults with atopic dermatitis experienced at least a 50% improvement in EASI scores, a big improvement in itch, and reduced transepidermal water loss after 12 weeks of the bleach baths. As other investigators have reported, the bleach baths were very well tolerated and safe.
Dr. Beck reported serving as a consultant to eight pharmaceutical companies with an interest in developing new treatments for atopic dermatitis.
LOS ANGELES – For patients with severe atopic dermatitis and their families and treating physicians, there is big news: finally, there is light at the end of the tunnel, Dr. Lisa A. Beck declared in a plenary lecture at the annual meeting of the American Academy of Allergy, Asthma, and Immunology.
Better drugs are on the way. The new agents in the developmental pipeline target specific immunologic pathways that appear to be central to atopic dermatitis. Moreover, exciting recent evidence indicates it’s possible to noninvasively identify children at high risk for atopic dermatitis and intervene preventively to reduce the likelihood of actually developing the disease, according to Dr. Beck, professor of dermatology and medicine at the University of Rochester (N.Y.).
“Many pharmaceutical companies have now turned their attention to atopic dermatitis and aren’t just focusing on asthma anymore. The biggest pipeline appears to involve drugs that might target the Th2 [T helper 2 cells] pathway, either by trying to eliminate alarmins such as TSLP [thymic stromal lymphopoietin], or reverse the effects of the Th2 cytokines interleukin-4 and -13, either alone or together, or prevent the recruitment of activated T cells,” she said.
Dr. Beck presented an update on three such promising investigational approaches on the horizon: the IL-4 and IL-13 inhibitor dupilumab; oral and topical Janus associated kinase (JAK) inhibitors; and anti-IgE therapies.
Dupilumab: This fully human monoclonal antibody that blocks IL-4 and IL-13 is also being developed as a treatment for eosinophilic asthma. Dr. Beck was first author of a report on a series of four phase II randomized trials of dupilumab for moderate to severe atopic dermatitis in adults. The publication caused a stir, with dupilumab-treated patients showing marked and rapid improvement to a degree previously unseen in the treatment of this disease (N Engl J Med. 2014;371[2]:130-9).
In the 12-week study, for example, 85% of dupilumab-treated patients achieved at least a 50% improvement in the Eczema Area and Severity Index (EASI) score, compared with 35% of placebo-treated controls, with a significant between-group difference seen in the first week. Maximum improvement – a 75%-80% reduction in EASI scores – was noted at 6-8 weeks. Forty percent of dupilumab-treated patients achieved clear or near-clear skin by investigator’s global assessment, compared with just 7% of controls.
Itching decreased markedly beginning in the first week, too. The investigational agent’s side effect profile was similar to placebo. Phase III clinical trials in atopic dermatitis are ongoing.
A study by other investigators found that dupilumab resulted in rapid improvement in the molecular signature of atopic dermatitis in skin biopsy specimens (J Allergy Clin Immunol. 2014 Dec;134[6]:1293-300). The observed changes in gene expression suggest that dupilumab might have a beneficial effect on the dysfunctional skin barrier that is a hallmark of atopic dermatitis. Further studies are now being planned to take a closer look at that possibility.
JAK inhibitors: “We’re all really excited about this approach because dogs, too, get allergic dermatitis, and in 2013 a JAK 1 and 3 inhibitor [oclacitinib, Apoquel] was approved as a veterinary medicine therapy. It has resulted in dramatic improvement in itch within 1 week of administration, as well as significant improvement in the dermatitis,” Dr. Beck said.
Three JAK inhibitors are now in phase II clinical trials for atopic dermatitis in humans: the JAK 1 and 3 inhibitor tofacitinib (Xeljanz), both as a topical ointment and the familiar oral formulation; baricitinib, an oral JAK 1 and 2 inhibitor; and an agent known for now as PF-04965842, which is an oral inhibitor specifically of JAK 1.
“JAK inhibitors have been quite effective in treating a number of other inflammatory conditions, as well as cancers. I think they will have a role in the treatment of atopic dermatitis. The biggest concerns will be the off-target effects,” she predicted.
Anti-IgE agents: Omalizumab (Xolair), a humanized monoclonal antibody that binds to IgE, has gotten mixed reviews as an investigational treatment for atopic dermatitis. The best study to date, a randomized, single-center, placebo-controlled, double-blind, 16-week clinical trial, found that omalizumab depleted IgE but didn’t improve the clinical course of atopic dermatitis (J Dtsch Dermatol Ges. 2010 Dec;8[12]:990-8). Nonetheless, a phase II trial of omalizumab is ongoing. Plus, ligelizumab, an anti-IgE monoclonal antibody with a higher affinity for IgE than omalizumab, is also in a phase II trial for adult atopic dermatitis.
“Anti-IgE therapy, I think, is still not dead in atopic dermatitis. I look forward to seeing whether omalizumab will work in unique subsets of patients, or whether a more potent anti-IgE molecule will be more beneficial,” Dr. Beck commented.
As exciting as the prospects are for these investigational agents, there also have been several recent important advances in the prevention of atopic dermatitis, she continued. Investigators led by Dr. Alan D. Irvine of Trinity College, Dublin, noninvasively measured transepidermal water loss in early infancy in more than 1,900 Irish 2-day-old infants and found that those in the 75th percentile for this early marker of skin barrier dysfunction were at 3.1-fold increased risk for diagnosis of atopic dermatitis by age 2 years (J Allergy Clin Immunol. 2016 Apr;137[4]:1111-6). This new-found ability to identify at-risk infants will be extremely helpful in designing atopic dermatitis prevention studies, according to Dr. Beck.
The other advance in prevention was provided via a randomized trial by Dr. Eric L. Simpson of Oregon Health and Science University, Portland, and his coinvestigators. They randomized a group of infants at high risk for atopic dermatitis to daily application of any of five OTC skin moisturizers or a no-moisturizer control group from 2 weeks through 6 months of age. The study hypothesis was that the moisturizers would help reverse the skin barrier abnormalities that play a key role in atopic dermatitis. The hypothesis was borne out by the finding that there was at least a 50% reduction in physician-diagnosed atopic dermatitis by age 6 months in the daily moisturizer group (J Allergy Clin Immunol. 2014 Oct;134[4]:818-23).
Dr. Beck concluded by describing a likely near-term atopic dermatitis prevention and management scenario: High-risk infants will be identified on the basis of noninvasive assessment of epithelial features, such as transepidermal water loss or the presence of high levels of thymic stromal lymphopoietin on the skin surface. Encouragement of daily moisturizing for these high-risk infants will prevent some of them from going on to develop eczema.
For those who do get eczema, dilute bleach baths will help in restoring normal skin barrier function, as was confirmed in an in-press study by Dr. Beck and her coinvestigators, who found that 46% of a group of adults with atopic dermatitis experienced at least a 50% improvement in EASI scores, a big improvement in itch, and reduced transepidermal water loss after 12 weeks of the bleach baths. As other investigators have reported, the bleach baths were very well tolerated and safe.
Dr. Beck reported serving as a consultant to eight pharmaceutical companies with an interest in developing new treatments for atopic dermatitis.
LOS ANGELES – For patients with severe atopic dermatitis and their families and treating physicians, there is big news: finally, there is light at the end of the tunnel, Dr. Lisa A. Beck declared in a plenary lecture at the annual meeting of the American Academy of Allergy, Asthma, and Immunology.
Better drugs are on the way. The new agents in the developmental pipeline target specific immunologic pathways that appear to be central to atopic dermatitis. Moreover, exciting recent evidence indicates it’s possible to noninvasively identify children at high risk for atopic dermatitis and intervene preventively to reduce the likelihood of actually developing the disease, according to Dr. Beck, professor of dermatology and medicine at the University of Rochester (N.Y.).
“Many pharmaceutical companies have now turned their attention to atopic dermatitis and aren’t just focusing on asthma anymore. The biggest pipeline appears to involve drugs that might target the Th2 [T helper 2 cells] pathway, either by trying to eliminate alarmins such as TSLP [thymic stromal lymphopoietin], or reverse the effects of the Th2 cytokines interleukin-4 and -13, either alone or together, or prevent the recruitment of activated T cells,” she said.
Dr. Beck presented an update on three such promising investigational approaches on the horizon: the IL-4 and IL-13 inhibitor dupilumab; oral and topical Janus associated kinase (JAK) inhibitors; and anti-IgE therapies.
Dupilumab: This fully human monoclonal antibody that blocks IL-4 and IL-13 is also being developed as a treatment for eosinophilic asthma. Dr. Beck was first author of a report on a series of four phase II randomized trials of dupilumab for moderate to severe atopic dermatitis in adults. The publication caused a stir, with dupilumab-treated patients showing marked and rapid improvement to a degree previously unseen in the treatment of this disease (N Engl J Med. 2014;371[2]:130-9).
In the 12-week study, for example, 85% of dupilumab-treated patients achieved at least a 50% improvement in the Eczema Area and Severity Index (EASI) score, compared with 35% of placebo-treated controls, with a significant between-group difference seen in the first week. Maximum improvement – a 75%-80% reduction in EASI scores – was noted at 6-8 weeks. Forty percent of dupilumab-treated patients achieved clear or near-clear skin by investigator’s global assessment, compared with just 7% of controls.
Itching decreased markedly beginning in the first week, too. The investigational agent’s side effect profile was similar to placebo. Phase III clinical trials in atopic dermatitis are ongoing.
A study by other investigators found that dupilumab resulted in rapid improvement in the molecular signature of atopic dermatitis in skin biopsy specimens (J Allergy Clin Immunol. 2014 Dec;134[6]:1293-300). The observed changes in gene expression suggest that dupilumab might have a beneficial effect on the dysfunctional skin barrier that is a hallmark of atopic dermatitis. Further studies are now being planned to take a closer look at that possibility.
JAK inhibitors: “We’re all really excited about this approach because dogs, too, get allergic dermatitis, and in 2013 a JAK 1 and 3 inhibitor [oclacitinib, Apoquel] was approved as a veterinary medicine therapy. It has resulted in dramatic improvement in itch within 1 week of administration, as well as significant improvement in the dermatitis,” Dr. Beck said.
Three JAK inhibitors are now in phase II clinical trials for atopic dermatitis in humans: the JAK 1 and 3 inhibitor tofacitinib (Xeljanz), both as a topical ointment and the familiar oral formulation; baricitinib, an oral JAK 1 and 2 inhibitor; and an agent known for now as PF-04965842, which is an oral inhibitor specifically of JAK 1.
“JAK inhibitors have been quite effective in treating a number of other inflammatory conditions, as well as cancers. I think they will have a role in the treatment of atopic dermatitis. The biggest concerns will be the off-target effects,” she predicted.
Anti-IgE agents: Omalizumab (Xolair), a humanized monoclonal antibody that binds to IgE, has gotten mixed reviews as an investigational treatment for atopic dermatitis. The best study to date, a randomized, single-center, placebo-controlled, double-blind, 16-week clinical trial, found that omalizumab depleted IgE but didn’t improve the clinical course of atopic dermatitis (J Dtsch Dermatol Ges. 2010 Dec;8[12]:990-8). Nonetheless, a phase II trial of omalizumab is ongoing. Plus, ligelizumab, an anti-IgE monoclonal antibody with a higher affinity for IgE than omalizumab, is also in a phase II trial for adult atopic dermatitis.
“Anti-IgE therapy, I think, is still not dead in atopic dermatitis. I look forward to seeing whether omalizumab will work in unique subsets of patients, or whether a more potent anti-IgE molecule will be more beneficial,” Dr. Beck commented.
As exciting as the prospects are for these investigational agents, there also have been several recent important advances in the prevention of atopic dermatitis, she continued. Investigators led by Dr. Alan D. Irvine of Trinity College, Dublin, noninvasively measured transepidermal water loss in early infancy in more than 1,900 Irish 2-day-old infants and found that those in the 75th percentile for this early marker of skin barrier dysfunction were at 3.1-fold increased risk for diagnosis of atopic dermatitis by age 2 years (J Allergy Clin Immunol. 2016 Apr;137[4]:1111-6). This new-found ability to identify at-risk infants will be extremely helpful in designing atopic dermatitis prevention studies, according to Dr. Beck.
The other advance in prevention was provided via a randomized trial by Dr. Eric L. Simpson of Oregon Health and Science University, Portland, and his coinvestigators. They randomized a group of infants at high risk for atopic dermatitis to daily application of any of five OTC skin moisturizers or a no-moisturizer control group from 2 weeks through 6 months of age. The study hypothesis was that the moisturizers would help reverse the skin barrier abnormalities that play a key role in atopic dermatitis. The hypothesis was borne out by the finding that there was at least a 50% reduction in physician-diagnosed atopic dermatitis by age 6 months in the daily moisturizer group (J Allergy Clin Immunol. 2014 Oct;134[4]:818-23).
Dr. Beck concluded by describing a likely near-term atopic dermatitis prevention and management scenario: High-risk infants will be identified on the basis of noninvasive assessment of epithelial features, such as transepidermal water loss or the presence of high levels of thymic stromal lymphopoietin on the skin surface. Encouragement of daily moisturizing for these high-risk infants will prevent some of them from going on to develop eczema.
For those who do get eczema, dilute bleach baths will help in restoring normal skin barrier function, as was confirmed in an in-press study by Dr. Beck and her coinvestigators, who found that 46% of a group of adults with atopic dermatitis experienced at least a 50% improvement in EASI scores, a big improvement in itch, and reduced transepidermal water loss after 12 weeks of the bleach baths. As other investigators have reported, the bleach baths were very well tolerated and safe.
Dr. Beck reported serving as a consultant to eight pharmaceutical companies with an interest in developing new treatments for atopic dermatitis.
EXPERT ANALYSIS FROM THE 2016 AAAAI ANNUAL MEETING
Prevalence of Glaucoma in Patients With Vitiligo
Vitiligo is an acquired idiopathic disease of unknown etiology. Characterized by depigmented maculae and melanocytic destruction, it usually presents in childhood or young adulthood. The incidence of vitiligo ranges from 0.5% to 2% globally and there is no racial or gender predilection.1
Patients with vitiligo may exhibit pigmentary abnormalities of the iris and retina.2 Noninflammatory depigmented lesions of the ocular fundus observed in vitiligo indicate a local loss of melanocytes.1 The fact that melanocytes are present not only in the skin and roots of the hair but also in the uvea and stria vascularis of the inner ear may explain the ophthalmologic disorders that accompany vitiligo.3 The term glaucoma refers to a large number of diseases that share a common feature: a distinctive and progressive optic neuropathy that may derive from various risks and is associated with a gradual loss of the visual field. If the disorder is not diagnosed and treated properly it could cause blindness.
Glaucoma is classified on the basis of the underlying abnormality that causes intraocular pressure (IOP) to rise. Glaucoma is first divided into open-angle and angle-closure glaucoma; glaucoma associated with developmental anomalies is then subdivided according to specific alterations.4
A PubMed search of articles indexed for MEDLINE using the terms vitiligo and glaucoma revealed only 1 study examining the incidence of glaucoma in patients with vitiligo.5 In the study reported here, we determined the presence of and possible risk factors for glaucoma in patients with vitiligo who had presented to the dermatology polyclinic.
Methods
We registered 49 patients diagnosed with vitiligo by clinical and Wood light examination and 20 age- and sex-matched healthy controls. Patients who were using topical corticosteroid treatments for vitiligo lesions located on the face were excluded from the study due to the glaucoma-inducing effects of corticosteroids. Similarly, patients who received drugs with sympathetic and parasympathetic action that can cause glaucoma were excluded.
The patients received a comprehensive ophthalmologic examination that included visual acuity testing, refraction, IOP measurement, gonioscopy, and fundus examination. All patients and controls underwent visual field tests and optic nerve head analyses using a confocal scanning laser ophthalmoscope. Glaucoma was diagnosed based on fundus examination, IOP measurement, field of vision evaluation, and optic nerve head analysis.
Informed consent was obtained from all participants. The research protocol was approved by the university hospital ethics committee.
Results
The study registered a total of 49 patients with vitiligo (28 female; 21 male) and 20 healthy controls (10 female; 10 male) with a variety of demographic and clinical characteristics (Table 1).
Mean (SD) IOP values were 13.83 (2.84) mm Hg for the right eye and 13.89 (2.60) mm Hg for the left eye in the vitiligo group. Values were 14.35 (2.56) mm Hg and 14.95 (2.92) mm Hg, respectively, in the control group. The IOP differences between the 2 groups were not statistically significant (P>.05).
Nine patients (18.4%) in the vitiligo group were found to have signs of normal-tension glaucoma (NTG). Optic nerve damage and vision loss occurs in the presence of normal IOP in NTG. There were no signs of NTG in the control group. Normal-tension glaucoma was diagnosed in the vitiligo group based on glaucomatous optic disc appearance, visual field defects, and structural analysis of the entire optic nerve head in confocal scanning laser ophthalmoscope. The NTG difference between the vitiligo and control groups was statistically significant (P=.04).
In the vitiligo group, of the 9 patients who had NTG, 6 had periorbital vitiligo lesions; the remaining 3 had none. Although patients who had periorbital lesions had a higher rate of glaucoma relative to the patients without periorbital lesions, the difference was not statistically significant (P>.05).
No statistically significant differences (P>.05) were found between patients with vitiligo with and without glaucoma in terms of age, sex, disease duration, family history of vitiligo, presence or absence of periorbital involvement, manner of involvement, percentage of the involved body areas, and IOP (Table 1).
Comment
Glaucoma is characterized by increased IOP, visual field loss, and changes in the optic nerve head. Although elevated IOP is common in ocular hypertension as well as in glaucoma, there is no glaucomatous visual field loss in ocular hypertension. In NTG, on the other hand, glaucomatous visual field loss and optic nerve head changes occur without an increase in IOP.6 Normal-tension glaucoma is a particular type of open-angle glaucoma. It is believed that NTG and high-tension glaucoma induce optic nerve head damage through different means.7 Alternative theories have been put forth to account for the glaucomatous damage to the optic nerve head that occurs in NTG, despite normal or close to normal IOP. These theories include vascular disorders (eg, ischemia, which interrupts the orthograde or retrograde axonal transport), excessive accumulation of free radicals, triggering of apoptosis, and low resistance of lamina cribrosa.8
Although there are various studies exploring ocular symptoms in patients with vitiligo,9-15 only 1 study has examined the incidence of glaucoma in this group of patients.5 Biswas et al11 examined ocular signs in 100 patients with vitiligo and found that 23% of patients had hypopigmented foci in the iris, 18% had pigmentation in the anterior chamber, 11% had chorioretinal degeneration, 9% had hypopigmentation of the retinal pigment epithelium, 5% had uveitis, and 34% were evaluated as normal. In this study, the authors concluded that there was a strong relationship between vitiligo and eye diseases.11 When Gopal et al9 compared the eye examinations of 150 vitiligo patients and 100 healthy controls, they found uveitis, iris, and retinal pigmentary abnormalities in 16% of the vitiligo patients (P<.001).
Rogosić et al5 examined the incidence of glaucoma in 42 patients with vitiligo and found primary open-angle glaucoma in 24 (57%) patients. The patients had a mean age of 56 years, mean disease duration of 13 years, and mean IOP of 18 mm Hg for the right eye and 17.5 mm Hg for the left eye. The incidence of glaucoma was significantly higher in patients with vitiligo (P<.001) and increased with disease duration.5
Similar studies, however, have failed to show a relationship between vitiligo and glaucoma. In a study that evaluated the retinal pigment epithelium and the optic nerve in patients with vitiligo, Perossini et al10 found that the fundus examination of the patients was perfectly normal.
In our study, we detected NTG in 18.4% of patients with vitiligo. We did not find a significant statistical difference between patients with and without glaucoma (Table 2). Rogosić et al5 found a significant relationship between age and glaucoma incidence, but we did not find such a relationship, which we believe is because the mean age of our patients was lower than the prior study.
In vitiligo, melanocytes are destroyed through an unknown mechanism. Although the cellular and molecular mechanisms causing melanocytic destruction have not yet been determined, various hypotheses have been put forward to explain the etiopathogenesis of vitiligo. Among these, the most commonly held hypotheses are the neural, self-destruction, and autoimmune hypotheses.16
Based on the observation that stress and serious trauma could precipitate or trigger the onset of vitiligo,16 the neural hypothesis holds that neurochemical mediators released from the edges of the nerve endings exert toxic effects on melanocytes. The fact that both melanocytes and choroidal pigment cells originate from the mesenchyme and dermatomal spreading of segmental vitiligo are arguments propounded in favor of this hypothesis.17
The self-destruction hypothesis suggests that the intrinsic protective mechanisms that normally enable melanocytes to eliminate toxic intermediate products or metabolites on the melanogenesis path have been impaired in patients with vitiligo.18,19 There is evidence of increased oxidative stress over the whole epidermis of patients with vitiligo.20 Thus, free radicals affect melanin and cause membrane damage via lipid peroxidation reactions.21
The autoimmune hypothesis proposes a clinical relationship between vitiligo and several diseases believed to be autoimmune. Because the macrophage infiltration observed in vitiligo lesions is more pronounced on the perilesional skin, this hypothesis holds that macrophages may play a role in melanocyte removal.21 The Koebner phenomenon observed in vitiligo lends support to the critical role of trauma in the etiopathogenesis of the disease.
Although we could not explain the co-presence of vitiligo and glaucoma, we believe that it may result from the fact that both diseases are observed in tissues that have the same embryologic origin and etiology, perhaps vascular or neural disorders, excessive accumulation of free radicals, or the triggering of apoptosis. Dermatologists should be alert to the presence of glaucoma in patients with vitiligo because glaucoma is an eye disease that progresses slowly and may lead to vision loss.
1. Ortonne JP. Vitiligo and other disorders of hypopigmentation. In: Bolognia JB, Jorizzo JL, Rapini RP, eds. Dermatology. 1st ed. New York, NY: Mosby; 2003:947-973.
2. Ortonne JP, Bahadoran P, Fitzpatrick TB, et al. Hypomelanoses and hypermelanoses. In: Freedberg IM, Eisen AZ, Wolff K, eds. Fitzpatrick’s Dermatology in General Medicine. 6th ed. New York, NY: McGraw-Hill; 2003:836-881.
3. van den Wijngaard R, Wijngaard R, Wankowiczs-Kalinsa A, et al. Autoimmune melanocyte destruction in vitiligo. Lab Invest. 2001;81:1061-1067.
4. Shields MB, Ritch R, Krupin T. Classification of the glaucomas. In: Ritch R, Shields MB, Krupin T, eds. The Glaucomas. St Louis, MO: C.V. Mosby Co; 1996:717-725.
5. Rogosić V, Bojić L, Puizina-Ivić N, et al. Vitiligo and glaucoma–an association or a coincidence? a pilot study. Acta Dermatovenerol Croat. 2010;18:21-26.
6. Anderson DR. Normal-tension glaucoma (low-tension glaucoma). Indian J Ophthalmol. 2011;59(suppl 59):S97-S101.
7. Iwata K. Primary open angle glaucoma and low tension glaucoma–pathogenesis and mechanism of optic nerve damage [in Japanese]. Nippon Ganka Gakkai Zasshi. 1992;96:1501-1531.
8. Hitchings RA, Anderton SA. A comparative study of visual field defects seen in patients with low-tension glaucoma and chronic simple glaucoma. Br J Ophthalmol. 1983;67:818-821.
9. Gopal KV, Rama Rao GR, Kumar YH, et al. Vitiligo: a part of a systemic autoimmune process. Indian J Dermatol Venereol Leprol. 2007;73:162-165.
10. Perossini M, Turio E, Perossini T, et al. Vitiligo: ocular and electrophysiological findings. G Ital Dermatol Venereol. 2010;145:141-149.
11. Biswas G, Barbhuiya JN, Biswas MC, et al. Clinical pattern of ocular manifestations in vitiligo. J Indian Med Assoc. 2003;101:478-480.
12. Park S, Albert DM, Bolognia JL. Ocular manifestations of pigmentary disorders. Dermatol Clin. 1992;10:609-622.
13. Albert DM, Nordlund JJ, Lerner AB. Ocular abnormalities occurring with vitiligo. Ophthalmology. 1979;86:1145-1160.
14. Wagoner MD, Albert DM, Lerner AB, et al. New observations on vitiligo and ocular disease. Am J Ophthalmol. 1983;96:16-26.
15. Cowan CL Jr, Halder RM, Grimes PE, et al. Ocular disturbances in vitiligo. J Am Acad Dermatol. 1986;15:17-24.
16. Orecchia GE. Neural pathogenesis. In: Hann SK, Nordlund JJ. Vitiligo. Oxford, England: Blackwell Science Ltd; 2000:142-150.
17. Braun-Falco O, Plewig G, Wolf HH, et al. Disorders of melanin pigmentation. In: Bartels V, ed. Dermatology. Berlin, Germany: Springer; 2000:1013-1042.
18. Tüzün Y, Kotoğyan A, Aydemir EH, et al. Pigmentasyon bozuklukları. In: Baransü O. Dermatoloji. 2nd ed. Istanbul: Nobel Tıp Kitabevi; 1994:557-559.
19. Odom RB, James WD, Berger TG. Disturbances of pigmentation. In: Odom RB, James WD, Berger TG. Andrews’ Diseases of the Skin. 9th ed. Philadelphia, PA: W.B. Saunders Company; 2000:1065-1068.
20. Schallreuter KU. Biochemical theory of vitiligo: a role of pteridines in pigmentation. In: Hann SK, Nordlund JJ. Vitiligo. London, England: Blackwell Science Ltd; 2000:151-159.
21. van den Wijngaard R, Wankowicz-Kalinska A, Le Poole C, et al. Local immune response in skin of generalized vitiligo patients. destruction of melanocytes is associated with the predominent presence of CLA+T cells at the perilesional site. Lab Invest. 2000;80:1299-1309.
Vitiligo is an acquired idiopathic disease of unknown etiology. Characterized by depigmented maculae and melanocytic destruction, it usually presents in childhood or young adulthood. The incidence of vitiligo ranges from 0.5% to 2% globally and there is no racial or gender predilection.1
Patients with vitiligo may exhibit pigmentary abnormalities of the iris and retina.2 Noninflammatory depigmented lesions of the ocular fundus observed in vitiligo indicate a local loss of melanocytes.1 The fact that melanocytes are present not only in the skin and roots of the hair but also in the uvea and stria vascularis of the inner ear may explain the ophthalmologic disorders that accompany vitiligo.3 The term glaucoma refers to a large number of diseases that share a common feature: a distinctive and progressive optic neuropathy that may derive from various risks and is associated with a gradual loss of the visual field. If the disorder is not diagnosed and treated properly it could cause blindness.
Glaucoma is classified on the basis of the underlying abnormality that causes intraocular pressure (IOP) to rise. Glaucoma is first divided into open-angle and angle-closure glaucoma; glaucoma associated with developmental anomalies is then subdivided according to specific alterations.4
A PubMed search of articles indexed for MEDLINE using the terms vitiligo and glaucoma revealed only 1 study examining the incidence of glaucoma in patients with vitiligo.5 In the study reported here, we determined the presence of and possible risk factors for glaucoma in patients with vitiligo who had presented to the dermatology polyclinic.
Methods
We registered 49 patients diagnosed with vitiligo by clinical and Wood light examination and 20 age- and sex-matched healthy controls. Patients who were using topical corticosteroid treatments for vitiligo lesions located on the face were excluded from the study due to the glaucoma-inducing effects of corticosteroids. Similarly, patients who received drugs with sympathetic and parasympathetic action that can cause glaucoma were excluded.
The patients received a comprehensive ophthalmologic examination that included visual acuity testing, refraction, IOP measurement, gonioscopy, and fundus examination. All patients and controls underwent visual field tests and optic nerve head analyses using a confocal scanning laser ophthalmoscope. Glaucoma was diagnosed based on fundus examination, IOP measurement, field of vision evaluation, and optic nerve head analysis.
Informed consent was obtained from all participants. The research protocol was approved by the university hospital ethics committee.
Results
The study registered a total of 49 patients with vitiligo (28 female; 21 male) and 20 healthy controls (10 female; 10 male) with a variety of demographic and clinical characteristics (Table 1).
Mean (SD) IOP values were 13.83 (2.84) mm Hg for the right eye and 13.89 (2.60) mm Hg for the left eye in the vitiligo group. Values were 14.35 (2.56) mm Hg and 14.95 (2.92) mm Hg, respectively, in the control group. The IOP differences between the 2 groups were not statistically significant (P>.05).
Nine patients (18.4%) in the vitiligo group were found to have signs of normal-tension glaucoma (NTG). Optic nerve damage and vision loss occurs in the presence of normal IOP in NTG. There were no signs of NTG in the control group. Normal-tension glaucoma was diagnosed in the vitiligo group based on glaucomatous optic disc appearance, visual field defects, and structural analysis of the entire optic nerve head in confocal scanning laser ophthalmoscope. The NTG difference between the vitiligo and control groups was statistically significant (P=.04).
In the vitiligo group, of the 9 patients who had NTG, 6 had periorbital vitiligo lesions; the remaining 3 had none. Although patients who had periorbital lesions had a higher rate of glaucoma relative to the patients without periorbital lesions, the difference was not statistically significant (P>.05).
No statistically significant differences (P>.05) were found between patients with vitiligo with and without glaucoma in terms of age, sex, disease duration, family history of vitiligo, presence or absence of periorbital involvement, manner of involvement, percentage of the involved body areas, and IOP (Table 1).
Comment
Glaucoma is characterized by increased IOP, visual field loss, and changes in the optic nerve head. Although elevated IOP is common in ocular hypertension as well as in glaucoma, there is no glaucomatous visual field loss in ocular hypertension. In NTG, on the other hand, glaucomatous visual field loss and optic nerve head changes occur without an increase in IOP.6 Normal-tension glaucoma is a particular type of open-angle glaucoma. It is believed that NTG and high-tension glaucoma induce optic nerve head damage through different means.7 Alternative theories have been put forth to account for the glaucomatous damage to the optic nerve head that occurs in NTG, despite normal or close to normal IOP. These theories include vascular disorders (eg, ischemia, which interrupts the orthograde or retrograde axonal transport), excessive accumulation of free radicals, triggering of apoptosis, and low resistance of lamina cribrosa.8
Although there are various studies exploring ocular symptoms in patients with vitiligo,9-15 only 1 study has examined the incidence of glaucoma in this group of patients.5 Biswas et al11 examined ocular signs in 100 patients with vitiligo and found that 23% of patients had hypopigmented foci in the iris, 18% had pigmentation in the anterior chamber, 11% had chorioretinal degeneration, 9% had hypopigmentation of the retinal pigment epithelium, 5% had uveitis, and 34% were evaluated as normal. In this study, the authors concluded that there was a strong relationship between vitiligo and eye diseases.11 When Gopal et al9 compared the eye examinations of 150 vitiligo patients and 100 healthy controls, they found uveitis, iris, and retinal pigmentary abnormalities in 16% of the vitiligo patients (P<.001).
Rogosić et al5 examined the incidence of glaucoma in 42 patients with vitiligo and found primary open-angle glaucoma in 24 (57%) patients. The patients had a mean age of 56 years, mean disease duration of 13 years, and mean IOP of 18 mm Hg for the right eye and 17.5 mm Hg for the left eye. The incidence of glaucoma was significantly higher in patients with vitiligo (P<.001) and increased with disease duration.5
Similar studies, however, have failed to show a relationship between vitiligo and glaucoma. In a study that evaluated the retinal pigment epithelium and the optic nerve in patients with vitiligo, Perossini et al10 found that the fundus examination of the patients was perfectly normal.
In our study, we detected NTG in 18.4% of patients with vitiligo. We did not find a significant statistical difference between patients with and without glaucoma (Table 2). Rogosić et al5 found a significant relationship between age and glaucoma incidence, but we did not find such a relationship, which we believe is because the mean age of our patients was lower than the prior study.
In vitiligo, melanocytes are destroyed through an unknown mechanism. Although the cellular and molecular mechanisms causing melanocytic destruction have not yet been determined, various hypotheses have been put forward to explain the etiopathogenesis of vitiligo. Among these, the most commonly held hypotheses are the neural, self-destruction, and autoimmune hypotheses.16
Based on the observation that stress and serious trauma could precipitate or trigger the onset of vitiligo,16 the neural hypothesis holds that neurochemical mediators released from the edges of the nerve endings exert toxic effects on melanocytes. The fact that both melanocytes and choroidal pigment cells originate from the mesenchyme and dermatomal spreading of segmental vitiligo are arguments propounded in favor of this hypothesis.17
The self-destruction hypothesis suggests that the intrinsic protective mechanisms that normally enable melanocytes to eliminate toxic intermediate products or metabolites on the melanogenesis path have been impaired in patients with vitiligo.18,19 There is evidence of increased oxidative stress over the whole epidermis of patients with vitiligo.20 Thus, free radicals affect melanin and cause membrane damage via lipid peroxidation reactions.21
The autoimmune hypothesis proposes a clinical relationship between vitiligo and several diseases believed to be autoimmune. Because the macrophage infiltration observed in vitiligo lesions is more pronounced on the perilesional skin, this hypothesis holds that macrophages may play a role in melanocyte removal.21 The Koebner phenomenon observed in vitiligo lends support to the critical role of trauma in the etiopathogenesis of the disease.
Although we could not explain the co-presence of vitiligo and glaucoma, we believe that it may result from the fact that both diseases are observed in tissues that have the same embryologic origin and etiology, perhaps vascular or neural disorders, excessive accumulation of free radicals, or the triggering of apoptosis. Dermatologists should be alert to the presence of glaucoma in patients with vitiligo because glaucoma is an eye disease that progresses slowly and may lead to vision loss.
Vitiligo is an acquired idiopathic disease of unknown etiology. Characterized by depigmented maculae and melanocytic destruction, it usually presents in childhood or young adulthood. The incidence of vitiligo ranges from 0.5% to 2% globally and there is no racial or gender predilection.1
Patients with vitiligo may exhibit pigmentary abnormalities of the iris and retina.2 Noninflammatory depigmented lesions of the ocular fundus observed in vitiligo indicate a local loss of melanocytes.1 The fact that melanocytes are present not only in the skin and roots of the hair but also in the uvea and stria vascularis of the inner ear may explain the ophthalmologic disorders that accompany vitiligo.3 The term glaucoma refers to a large number of diseases that share a common feature: a distinctive and progressive optic neuropathy that may derive from various risks and is associated with a gradual loss of the visual field. If the disorder is not diagnosed and treated properly it could cause blindness.
Glaucoma is classified on the basis of the underlying abnormality that causes intraocular pressure (IOP) to rise. Glaucoma is first divided into open-angle and angle-closure glaucoma; glaucoma associated with developmental anomalies is then subdivided according to specific alterations.4
A PubMed search of articles indexed for MEDLINE using the terms vitiligo and glaucoma revealed only 1 study examining the incidence of glaucoma in patients with vitiligo.5 In the study reported here, we determined the presence of and possible risk factors for glaucoma in patients with vitiligo who had presented to the dermatology polyclinic.
Methods
We registered 49 patients diagnosed with vitiligo by clinical and Wood light examination and 20 age- and sex-matched healthy controls. Patients who were using topical corticosteroid treatments for vitiligo lesions located on the face were excluded from the study due to the glaucoma-inducing effects of corticosteroids. Similarly, patients who received drugs with sympathetic and parasympathetic action that can cause glaucoma were excluded.
The patients received a comprehensive ophthalmologic examination that included visual acuity testing, refraction, IOP measurement, gonioscopy, and fundus examination. All patients and controls underwent visual field tests and optic nerve head analyses using a confocal scanning laser ophthalmoscope. Glaucoma was diagnosed based on fundus examination, IOP measurement, field of vision evaluation, and optic nerve head analysis.
Informed consent was obtained from all participants. The research protocol was approved by the university hospital ethics committee.
Results
The study registered a total of 49 patients with vitiligo (28 female; 21 male) and 20 healthy controls (10 female; 10 male) with a variety of demographic and clinical characteristics (Table 1).
Mean (SD) IOP values were 13.83 (2.84) mm Hg for the right eye and 13.89 (2.60) mm Hg for the left eye in the vitiligo group. Values were 14.35 (2.56) mm Hg and 14.95 (2.92) mm Hg, respectively, in the control group. The IOP differences between the 2 groups were not statistically significant (P>.05).
Nine patients (18.4%) in the vitiligo group were found to have signs of normal-tension glaucoma (NTG). Optic nerve damage and vision loss occurs in the presence of normal IOP in NTG. There were no signs of NTG in the control group. Normal-tension glaucoma was diagnosed in the vitiligo group based on glaucomatous optic disc appearance, visual field defects, and structural analysis of the entire optic nerve head in confocal scanning laser ophthalmoscope. The NTG difference between the vitiligo and control groups was statistically significant (P=.04).
In the vitiligo group, of the 9 patients who had NTG, 6 had periorbital vitiligo lesions; the remaining 3 had none. Although patients who had periorbital lesions had a higher rate of glaucoma relative to the patients without periorbital lesions, the difference was not statistically significant (P>.05).
No statistically significant differences (P>.05) were found between patients with vitiligo with and without glaucoma in terms of age, sex, disease duration, family history of vitiligo, presence or absence of periorbital involvement, manner of involvement, percentage of the involved body areas, and IOP (Table 1).
Comment
Glaucoma is characterized by increased IOP, visual field loss, and changes in the optic nerve head. Although elevated IOP is common in ocular hypertension as well as in glaucoma, there is no glaucomatous visual field loss in ocular hypertension. In NTG, on the other hand, glaucomatous visual field loss and optic nerve head changes occur without an increase in IOP.6 Normal-tension glaucoma is a particular type of open-angle glaucoma. It is believed that NTG and high-tension glaucoma induce optic nerve head damage through different means.7 Alternative theories have been put forth to account for the glaucomatous damage to the optic nerve head that occurs in NTG, despite normal or close to normal IOP. These theories include vascular disorders (eg, ischemia, which interrupts the orthograde or retrograde axonal transport), excessive accumulation of free radicals, triggering of apoptosis, and low resistance of lamina cribrosa.8
Although there are various studies exploring ocular symptoms in patients with vitiligo,9-15 only 1 study has examined the incidence of glaucoma in this group of patients.5 Biswas et al11 examined ocular signs in 100 patients with vitiligo and found that 23% of patients had hypopigmented foci in the iris, 18% had pigmentation in the anterior chamber, 11% had chorioretinal degeneration, 9% had hypopigmentation of the retinal pigment epithelium, 5% had uveitis, and 34% were evaluated as normal. In this study, the authors concluded that there was a strong relationship between vitiligo and eye diseases.11 When Gopal et al9 compared the eye examinations of 150 vitiligo patients and 100 healthy controls, they found uveitis, iris, and retinal pigmentary abnormalities in 16% of the vitiligo patients (P<.001).
Rogosić et al5 examined the incidence of glaucoma in 42 patients with vitiligo and found primary open-angle glaucoma in 24 (57%) patients. The patients had a mean age of 56 years, mean disease duration of 13 years, and mean IOP of 18 mm Hg for the right eye and 17.5 mm Hg for the left eye. The incidence of glaucoma was significantly higher in patients with vitiligo (P<.001) and increased with disease duration.5
Similar studies, however, have failed to show a relationship between vitiligo and glaucoma. In a study that evaluated the retinal pigment epithelium and the optic nerve in patients with vitiligo, Perossini et al10 found that the fundus examination of the patients was perfectly normal.
In our study, we detected NTG in 18.4% of patients with vitiligo. We did not find a significant statistical difference between patients with and without glaucoma (Table 2). Rogosić et al5 found a significant relationship between age and glaucoma incidence, but we did not find such a relationship, which we believe is because the mean age of our patients was lower than the prior study.
In vitiligo, melanocytes are destroyed through an unknown mechanism. Although the cellular and molecular mechanisms causing melanocytic destruction have not yet been determined, various hypotheses have been put forward to explain the etiopathogenesis of vitiligo. Among these, the most commonly held hypotheses are the neural, self-destruction, and autoimmune hypotheses.16
Based on the observation that stress and serious trauma could precipitate or trigger the onset of vitiligo,16 the neural hypothesis holds that neurochemical mediators released from the edges of the nerve endings exert toxic effects on melanocytes. The fact that both melanocytes and choroidal pigment cells originate from the mesenchyme and dermatomal spreading of segmental vitiligo are arguments propounded in favor of this hypothesis.17
The self-destruction hypothesis suggests that the intrinsic protective mechanisms that normally enable melanocytes to eliminate toxic intermediate products or metabolites on the melanogenesis path have been impaired in patients with vitiligo.18,19 There is evidence of increased oxidative stress over the whole epidermis of patients with vitiligo.20 Thus, free radicals affect melanin and cause membrane damage via lipid peroxidation reactions.21
The autoimmune hypothesis proposes a clinical relationship between vitiligo and several diseases believed to be autoimmune. Because the macrophage infiltration observed in vitiligo lesions is more pronounced on the perilesional skin, this hypothesis holds that macrophages may play a role in melanocyte removal.21 The Koebner phenomenon observed in vitiligo lends support to the critical role of trauma in the etiopathogenesis of the disease.
Although we could not explain the co-presence of vitiligo and glaucoma, we believe that it may result from the fact that both diseases are observed in tissues that have the same embryologic origin and etiology, perhaps vascular or neural disorders, excessive accumulation of free radicals, or the triggering of apoptosis. Dermatologists should be alert to the presence of glaucoma in patients with vitiligo because glaucoma is an eye disease that progresses slowly and may lead to vision loss.
1. Ortonne JP. Vitiligo and other disorders of hypopigmentation. In: Bolognia JB, Jorizzo JL, Rapini RP, eds. Dermatology. 1st ed. New York, NY: Mosby; 2003:947-973.
2. Ortonne JP, Bahadoran P, Fitzpatrick TB, et al. Hypomelanoses and hypermelanoses. In: Freedberg IM, Eisen AZ, Wolff K, eds. Fitzpatrick’s Dermatology in General Medicine. 6th ed. New York, NY: McGraw-Hill; 2003:836-881.
3. van den Wijngaard R, Wijngaard R, Wankowiczs-Kalinsa A, et al. Autoimmune melanocyte destruction in vitiligo. Lab Invest. 2001;81:1061-1067.
4. Shields MB, Ritch R, Krupin T. Classification of the glaucomas. In: Ritch R, Shields MB, Krupin T, eds. The Glaucomas. St Louis, MO: C.V. Mosby Co; 1996:717-725.
5. Rogosić V, Bojić L, Puizina-Ivić N, et al. Vitiligo and glaucoma–an association or a coincidence? a pilot study. Acta Dermatovenerol Croat. 2010;18:21-26.
6. Anderson DR. Normal-tension glaucoma (low-tension glaucoma). Indian J Ophthalmol. 2011;59(suppl 59):S97-S101.
7. Iwata K. Primary open angle glaucoma and low tension glaucoma–pathogenesis and mechanism of optic nerve damage [in Japanese]. Nippon Ganka Gakkai Zasshi. 1992;96:1501-1531.
8. Hitchings RA, Anderton SA. A comparative study of visual field defects seen in patients with low-tension glaucoma and chronic simple glaucoma. Br J Ophthalmol. 1983;67:818-821.
9. Gopal KV, Rama Rao GR, Kumar YH, et al. Vitiligo: a part of a systemic autoimmune process. Indian J Dermatol Venereol Leprol. 2007;73:162-165.
10. Perossini M, Turio E, Perossini T, et al. Vitiligo: ocular and electrophysiological findings. G Ital Dermatol Venereol. 2010;145:141-149.
11. Biswas G, Barbhuiya JN, Biswas MC, et al. Clinical pattern of ocular manifestations in vitiligo. J Indian Med Assoc. 2003;101:478-480.
12. Park S, Albert DM, Bolognia JL. Ocular manifestations of pigmentary disorders. Dermatol Clin. 1992;10:609-622.
13. Albert DM, Nordlund JJ, Lerner AB. Ocular abnormalities occurring with vitiligo. Ophthalmology. 1979;86:1145-1160.
14. Wagoner MD, Albert DM, Lerner AB, et al. New observations on vitiligo and ocular disease. Am J Ophthalmol. 1983;96:16-26.
15. Cowan CL Jr, Halder RM, Grimes PE, et al. Ocular disturbances in vitiligo. J Am Acad Dermatol. 1986;15:17-24.
16. Orecchia GE. Neural pathogenesis. In: Hann SK, Nordlund JJ. Vitiligo. Oxford, England: Blackwell Science Ltd; 2000:142-150.
17. Braun-Falco O, Plewig G, Wolf HH, et al. Disorders of melanin pigmentation. In: Bartels V, ed. Dermatology. Berlin, Germany: Springer; 2000:1013-1042.
18. Tüzün Y, Kotoğyan A, Aydemir EH, et al. Pigmentasyon bozuklukları. In: Baransü O. Dermatoloji. 2nd ed. Istanbul: Nobel Tıp Kitabevi; 1994:557-559.
19. Odom RB, James WD, Berger TG. Disturbances of pigmentation. In: Odom RB, James WD, Berger TG. Andrews’ Diseases of the Skin. 9th ed. Philadelphia, PA: W.B. Saunders Company; 2000:1065-1068.
20. Schallreuter KU. Biochemical theory of vitiligo: a role of pteridines in pigmentation. In: Hann SK, Nordlund JJ. Vitiligo. London, England: Blackwell Science Ltd; 2000:151-159.
21. van den Wijngaard R, Wankowicz-Kalinska A, Le Poole C, et al. Local immune response in skin of generalized vitiligo patients. destruction of melanocytes is associated with the predominent presence of CLA+T cells at the perilesional site. Lab Invest. 2000;80:1299-1309.
1. Ortonne JP. Vitiligo and other disorders of hypopigmentation. In: Bolognia JB, Jorizzo JL, Rapini RP, eds. Dermatology. 1st ed. New York, NY: Mosby; 2003:947-973.
2. Ortonne JP, Bahadoran P, Fitzpatrick TB, et al. Hypomelanoses and hypermelanoses. In: Freedberg IM, Eisen AZ, Wolff K, eds. Fitzpatrick’s Dermatology in General Medicine. 6th ed. New York, NY: McGraw-Hill; 2003:836-881.
3. van den Wijngaard R, Wijngaard R, Wankowiczs-Kalinsa A, et al. Autoimmune melanocyte destruction in vitiligo. Lab Invest. 2001;81:1061-1067.
4. Shields MB, Ritch R, Krupin T. Classification of the glaucomas. In: Ritch R, Shields MB, Krupin T, eds. The Glaucomas. St Louis, MO: C.V. Mosby Co; 1996:717-725.
5. Rogosić V, Bojić L, Puizina-Ivić N, et al. Vitiligo and glaucoma–an association or a coincidence? a pilot study. Acta Dermatovenerol Croat. 2010;18:21-26.
6. Anderson DR. Normal-tension glaucoma (low-tension glaucoma). Indian J Ophthalmol. 2011;59(suppl 59):S97-S101.
7. Iwata K. Primary open angle glaucoma and low tension glaucoma–pathogenesis and mechanism of optic nerve damage [in Japanese]. Nippon Ganka Gakkai Zasshi. 1992;96:1501-1531.
8. Hitchings RA, Anderton SA. A comparative study of visual field defects seen in patients with low-tension glaucoma and chronic simple glaucoma. Br J Ophthalmol. 1983;67:818-821.
9. Gopal KV, Rama Rao GR, Kumar YH, et al. Vitiligo: a part of a systemic autoimmune process. Indian J Dermatol Venereol Leprol. 2007;73:162-165.
10. Perossini M, Turio E, Perossini T, et al. Vitiligo: ocular and electrophysiological findings. G Ital Dermatol Venereol. 2010;145:141-149.
11. Biswas G, Barbhuiya JN, Biswas MC, et al. Clinical pattern of ocular manifestations in vitiligo. J Indian Med Assoc. 2003;101:478-480.
12. Park S, Albert DM, Bolognia JL. Ocular manifestations of pigmentary disorders. Dermatol Clin. 1992;10:609-622.
13. Albert DM, Nordlund JJ, Lerner AB. Ocular abnormalities occurring with vitiligo. Ophthalmology. 1979;86:1145-1160.
14. Wagoner MD, Albert DM, Lerner AB, et al. New observations on vitiligo and ocular disease. Am J Ophthalmol. 1983;96:16-26.
15. Cowan CL Jr, Halder RM, Grimes PE, et al. Ocular disturbances in vitiligo. J Am Acad Dermatol. 1986;15:17-24.
16. Orecchia GE. Neural pathogenesis. In: Hann SK, Nordlund JJ. Vitiligo. Oxford, England: Blackwell Science Ltd; 2000:142-150.
17. Braun-Falco O, Plewig G, Wolf HH, et al. Disorders of melanin pigmentation. In: Bartels V, ed. Dermatology. Berlin, Germany: Springer; 2000:1013-1042.
18. Tüzün Y, Kotoğyan A, Aydemir EH, et al. Pigmentasyon bozuklukları. In: Baransü O. Dermatoloji. 2nd ed. Istanbul: Nobel Tıp Kitabevi; 1994:557-559.
19. Odom RB, James WD, Berger TG. Disturbances of pigmentation. In: Odom RB, James WD, Berger TG. Andrews’ Diseases of the Skin. 9th ed. Philadelphia, PA: W.B. Saunders Company; 2000:1065-1068.
20. Schallreuter KU. Biochemical theory of vitiligo: a role of pteridines in pigmentation. In: Hann SK, Nordlund JJ. Vitiligo. London, England: Blackwell Science Ltd; 2000:151-159.
21. van den Wijngaard R, Wankowicz-Kalinska A, Le Poole C, et al. Local immune response in skin of generalized vitiligo patients. destruction of melanocytes is associated with the predominent presence of CLA+T cells at the perilesional site. Lab Invest. 2000;80:1299-1309.
Practice Points
- Patients with vitiligo may exhibit pigmentary abnormalities of the iris and retina.
- Normal-tension glaucoma may develop in patients with vitiligo.
- Glaucoma progresses slowly and may lead to vision loss; as a result, dermatologists should be alert to the presence of glaucoma in vitiligo patients.
Long-Term Βeta-Blocker Use May Cause More Harm in Patients Undergoing Surgery
Clinical question: What is the harm associated with long-term beta-blocker therapy in patients with uncomplicated hypertension undergoing non-cardiac surgery?
Background: Given the recent concerns over the validity of prior studies, there is uncertainty about which patients benefit most from perioperative beta-blockade. Current guidelines suggest continuing beta-blockers in the perioperative period. More data are needed to delineate which patients maximally benefit from perioperative beta-blockade.
Study design: Association study.
Setting: Danish nationwide cohort of patients.
Synopsis: Study investigators included 55,320 uncomplicated hypertension (no cardiovascular, renal, or liver disease) patients >19 years of age on ≥2 antihypertensive drugs undergoing non-cardiac surgery. In the 14,664 patients who received beta-blockers, the rates of 30-day major adverse cardiovascular events (MACE; cardiovascular death, nonfatal ischemic stroke, and nonfatal myocardial infarction) and 30-day all-cause mortality were 1.32% and 1.93%, respectively. However, in the 40,676 patients who did not receive beta-blockers, 30-day MACEs and 30-day all-cause mortality rates were 0.84% and 1.32%, respectively (P<0.001). When looking at the individual MACEs, cardiovascular death was the only statistically significant event with higher incidence (0.9% versus 0.45%, P<0.001).
Combination therapy with beta-blocker and RAS inhibitor, calcium channel blockers, or thiazide was associated with statistically significant higher risks of MACEs and all-cause mortality when compared to the combination of RAS inhibitor plus thiazide. Men >70 years of age or undergoing urgent surgery had the highest risk of harm. This study was not a randomized control trial, so caution must be used when attributing causality to beta-blockers, MACEs, and all-cause mortality.
Bottom line: Antihypertensive regimens containing beta-blockers may increase risk of perioperative MACEs and all-cause mortality in patients with uncomplicated hypertension.
Citation: Jorgensen ME, Hlatky MA, Kober L, et al. β-blocker-associated risks in patients with uncomplicated hypertension undergoing noncardiac surgery. JAMA Intern Med. 2015;175(12):1923-1931.
Clinical question: What is the harm associated with long-term beta-blocker therapy in patients with uncomplicated hypertension undergoing non-cardiac surgery?
Background: Given the recent concerns over the validity of prior studies, there is uncertainty about which patients benefit most from perioperative beta-blockade. Current guidelines suggest continuing beta-blockers in the perioperative period. More data are needed to delineate which patients maximally benefit from perioperative beta-blockade.
Study design: Association study.
Setting: Danish nationwide cohort of patients.
Synopsis: Study investigators included 55,320 uncomplicated hypertension (no cardiovascular, renal, or liver disease) patients >19 years of age on ≥2 antihypertensive drugs undergoing non-cardiac surgery. In the 14,664 patients who received beta-blockers, the rates of 30-day major adverse cardiovascular events (MACE; cardiovascular death, nonfatal ischemic stroke, and nonfatal myocardial infarction) and 30-day all-cause mortality were 1.32% and 1.93%, respectively. However, in the 40,676 patients who did not receive beta-blockers, 30-day MACEs and 30-day all-cause mortality rates were 0.84% and 1.32%, respectively (P<0.001). When looking at the individual MACEs, cardiovascular death was the only statistically significant event with higher incidence (0.9% versus 0.45%, P<0.001).
Combination therapy with beta-blocker and RAS inhibitor, calcium channel blockers, or thiazide was associated with statistically significant higher risks of MACEs and all-cause mortality when compared to the combination of RAS inhibitor plus thiazide. Men >70 years of age or undergoing urgent surgery had the highest risk of harm. This study was not a randomized control trial, so caution must be used when attributing causality to beta-blockers, MACEs, and all-cause mortality.
Bottom line: Antihypertensive regimens containing beta-blockers may increase risk of perioperative MACEs and all-cause mortality in patients with uncomplicated hypertension.
Citation: Jorgensen ME, Hlatky MA, Kober L, et al. β-blocker-associated risks in patients with uncomplicated hypertension undergoing noncardiac surgery. JAMA Intern Med. 2015;175(12):1923-1931.
Clinical question: What is the harm associated with long-term beta-blocker therapy in patients with uncomplicated hypertension undergoing non-cardiac surgery?
Background: Given the recent concerns over the validity of prior studies, there is uncertainty about which patients benefit most from perioperative beta-blockade. Current guidelines suggest continuing beta-blockers in the perioperative period. More data are needed to delineate which patients maximally benefit from perioperative beta-blockade.
Study design: Association study.
Setting: Danish nationwide cohort of patients.
Synopsis: Study investigators included 55,320 uncomplicated hypertension (no cardiovascular, renal, or liver disease) patients >19 years of age on ≥2 antihypertensive drugs undergoing non-cardiac surgery. In the 14,664 patients who received beta-blockers, the rates of 30-day major adverse cardiovascular events (MACE; cardiovascular death, nonfatal ischemic stroke, and nonfatal myocardial infarction) and 30-day all-cause mortality were 1.32% and 1.93%, respectively. However, in the 40,676 patients who did not receive beta-blockers, 30-day MACEs and 30-day all-cause mortality rates were 0.84% and 1.32%, respectively (P<0.001). When looking at the individual MACEs, cardiovascular death was the only statistically significant event with higher incidence (0.9% versus 0.45%, P<0.001).
Combination therapy with beta-blocker and RAS inhibitor, calcium channel blockers, or thiazide was associated with statistically significant higher risks of MACEs and all-cause mortality when compared to the combination of RAS inhibitor plus thiazide. Men >70 years of age or undergoing urgent surgery had the highest risk of harm. This study was not a randomized control trial, so caution must be used when attributing causality to beta-blockers, MACEs, and all-cause mortality.
Bottom line: Antihypertensive regimens containing beta-blockers may increase risk of perioperative MACEs and all-cause mortality in patients with uncomplicated hypertension.
Citation: Jorgensen ME, Hlatky MA, Kober L, et al. β-blocker-associated risks in patients with uncomplicated hypertension undergoing noncardiac surgery. JAMA Intern Med. 2015;175(12):1923-1931.
Depression Common among Physicians in Training
Clinical question: What is the prevalence of depression or depressive symptoms in resident physicians?
Background: Depression in resident physicians can lead to poor-quality medical care, increased errors, and long-term morbidity. Prevalence of depression or depressive symptoms has varied in prior studies, and more data are needed to better understand the true prevalence.
Study design: Systematic review and meta-analysis.
Setting: Surgical and nonsurgical residency programs in North America, Asia, Europe, South America, and Africa
Synopsis: Thirty-one cross-sectional studies (9,447 individuals) and 23 longitudinal studies (8,113 individuals) from January 1963 to September 2015 were included in this analysis, with the majority using self-reporting to identify residents with depression or depressive symptoms. Overall prevalence of depression or depressive symptoms was 28.8%, with a range of 20.9% to 43.2%, depending on the screening tool (95% CI, 25.3%–32.5%; P<0.001). There was an increased prevalence in depression or depressive symptoms as the calendar year progressed (slope=0.5% per calendar year increase; 95% CI, 0.03%–0.09%), with no difference in prevalence rates between surgical versus nonsurgical residents, U.S. versus elsewhere, cross-sectional versus longitudinal, or interns versus upper-level residents.
Because studies were heterogeneous with respect to the screening tools and resident population, the prevalence of depression or depressive symptoms cannot be precisely determined.
Bottom line: Prevalence of depression or depressive symptoms ranged from 20.9% to 43.2%, with pooled prevalence of 28.8%, and increased with time.
Citation: Mata DA, Ramos MA, Bansal N, et al. Prevalence of depression and depressive symptoms among resident physicians: a systematic review and met-analysis. JAMA. 2015;314(22):2373-2383.
Clinical question: What is the prevalence of depression or depressive symptoms in resident physicians?
Background: Depression in resident physicians can lead to poor-quality medical care, increased errors, and long-term morbidity. Prevalence of depression or depressive symptoms has varied in prior studies, and more data are needed to better understand the true prevalence.
Study design: Systematic review and meta-analysis.
Setting: Surgical and nonsurgical residency programs in North America, Asia, Europe, South America, and Africa
Synopsis: Thirty-one cross-sectional studies (9,447 individuals) and 23 longitudinal studies (8,113 individuals) from January 1963 to September 2015 were included in this analysis, with the majority using self-reporting to identify residents with depression or depressive symptoms. Overall prevalence of depression or depressive symptoms was 28.8%, with a range of 20.9% to 43.2%, depending on the screening tool (95% CI, 25.3%–32.5%; P<0.001). There was an increased prevalence in depression or depressive symptoms as the calendar year progressed (slope=0.5% per calendar year increase; 95% CI, 0.03%–0.09%), with no difference in prevalence rates between surgical versus nonsurgical residents, U.S. versus elsewhere, cross-sectional versus longitudinal, or interns versus upper-level residents.
Because studies were heterogeneous with respect to the screening tools and resident population, the prevalence of depression or depressive symptoms cannot be precisely determined.
Bottom line: Prevalence of depression or depressive symptoms ranged from 20.9% to 43.2%, with pooled prevalence of 28.8%, and increased with time.
Citation: Mata DA, Ramos MA, Bansal N, et al. Prevalence of depression and depressive symptoms among resident physicians: a systematic review and met-analysis. JAMA. 2015;314(22):2373-2383.
Clinical question: What is the prevalence of depression or depressive symptoms in resident physicians?
Background: Depression in resident physicians can lead to poor-quality medical care, increased errors, and long-term morbidity. Prevalence of depression or depressive symptoms has varied in prior studies, and more data are needed to better understand the true prevalence.
Study design: Systematic review and meta-analysis.
Setting: Surgical and nonsurgical residency programs in North America, Asia, Europe, South America, and Africa
Synopsis: Thirty-one cross-sectional studies (9,447 individuals) and 23 longitudinal studies (8,113 individuals) from January 1963 to September 2015 were included in this analysis, with the majority using self-reporting to identify residents with depression or depressive symptoms. Overall prevalence of depression or depressive symptoms was 28.8%, with a range of 20.9% to 43.2%, depending on the screening tool (95% CI, 25.3%–32.5%; P<0.001). There was an increased prevalence in depression or depressive symptoms as the calendar year progressed (slope=0.5% per calendar year increase; 95% CI, 0.03%–0.09%), with no difference in prevalence rates between surgical versus nonsurgical residents, U.S. versus elsewhere, cross-sectional versus longitudinal, or interns versus upper-level residents.
Because studies were heterogeneous with respect to the screening tools and resident population, the prevalence of depression or depressive symptoms cannot be precisely determined.
Bottom line: Prevalence of depression or depressive symptoms ranged from 20.9% to 43.2%, with pooled prevalence of 28.8%, and increased with time.
Citation: Mata DA, Ramos MA, Bansal N, et al. Prevalence of depression and depressive symptoms among resident physicians: a systematic review and met-analysis. JAMA. 2015;314(22):2373-2383.
Breakfast Based on Whey Protein May Help Manage Type 2 Diabetes
NEW YORK (Reuters Health) - A breakfast rich in whey protein may help people with type 2 diabetes manage their illness better, new research from Israel suggests.
"Whey protein, a byproduct of cheese manufacturing, lowers postprandial glycemia more than other protein sources," said lead author Dr. Daniela Jakubowicz from Wolfson Medical Center at Tel Aviv University."
We found that in type 2 diabetes, increasing protein content at breakfast has a greater impact on weight loss, glycated hemoglobin (HbA1C), satiety and postprandial glycemia when the protein source is whey protein, compared with other protein sources, such as eggs, tuna and soy," she told Reuters Health by email.
Dr. Jakubowicz and her group presented their findings April 1 at ENDO 2016, the annual meeting of the Endocrine Society, in Boston.
They randomly assigned 48 overweight and obese patients with type 2 diabetes to one of three isocaloric diets. Over 12 weeks, everyone ate a large breakfast, a medium-sized lunch and a small dinner, but the amount and source of each group's breakfast proteins differed.
At breakfast, the 17 participants in the whey group ate 36 g of protein as part of a whey protein shake consisting of 40% carbohydrate, 40% protein and 20% fat. The 16 participants in the high-protein group ate 36 g of protein in the form of eggs, tuna and cheese (40% carbs; 40% protein; 20% fat). The 15 in the high-carbohydrate group ate 13 g of protein in ready-to-eat cereals (65% carbs; 15% protein; 20% fat).
All three diets included a 660 kcal breakfast, a 567 cal lunch and a 276 cal dinner, with the same composition at lunch and dinner.
After 12 weeks, the participants in the whey protein group lost the most weight (7.6 kg vs. 6.1 kg for participants in the high-protein group and 3.5 kg for those in the high-carbohydrate group (p<0.0001).
Participants on the whey protein diet were less hungry during the day and had lower glucose spikes after meals compared with those on the other two diets.
The drop in HbA1C was 11.5% in the whey group, 7.7% in the protein group and 4.6% in the carbohydrate group (p<0.0001). Compared with the carbohydrate group, the percentage drop in HbA1c was greater by 41% in the protein group and by 64% in the whey group (p<0.0001).
"Whey protein was consumed only at breakfast; however, the improvement of glucose, insulin and glucagon-like peptide 1 (GLP-1) was also observed after lunch and dinner. The mechanism of this persistent beneficial effect of whey protein needs further research," Dr. Jakubowicz said.
Co-author Dr. Julio Wainstein, also at Wolfson Medical Center, added by email, "Usually, patients with type 2 diabetes are treated with a combination of several antidiabetic drugs to achieve adequate glucose regulation and decrease HbA1c. Whey protein should be considered an important adjuvant in the management of type 2 diabetes."
"Furthermore," Dr. Wainstein added, "it is possible that by adding whey protein to the diet, glucose regulation might be achieved with less medication, which is a valuable advantage in type 2 diabetes treatment."
The study had no commercial funding, and the authors declared no conflicts of interest.
NEW YORK (Reuters Health) - A breakfast rich in whey protein may help people with type 2 diabetes manage their illness better, new research from Israel suggests.
"Whey protein, a byproduct of cheese manufacturing, lowers postprandial glycemia more than other protein sources," said lead author Dr. Daniela Jakubowicz from Wolfson Medical Center at Tel Aviv University."
We found that in type 2 diabetes, increasing protein content at breakfast has a greater impact on weight loss, glycated hemoglobin (HbA1C), satiety and postprandial glycemia when the protein source is whey protein, compared with other protein sources, such as eggs, tuna and soy," she told Reuters Health by email.
Dr. Jakubowicz and her group presented their findings April 1 at ENDO 2016, the annual meeting of the Endocrine Society, in Boston.
They randomly assigned 48 overweight and obese patients with type 2 diabetes to one of three isocaloric diets. Over 12 weeks, everyone ate a large breakfast, a medium-sized lunch and a small dinner, but the amount and source of each group's breakfast proteins differed.
At breakfast, the 17 participants in the whey group ate 36 g of protein as part of a whey protein shake consisting of 40% carbohydrate, 40% protein and 20% fat. The 16 participants in the high-protein group ate 36 g of protein in the form of eggs, tuna and cheese (40% carbs; 40% protein; 20% fat). The 15 in the high-carbohydrate group ate 13 g of protein in ready-to-eat cereals (65% carbs; 15% protein; 20% fat).
All three diets included a 660 kcal breakfast, a 567 cal lunch and a 276 cal dinner, with the same composition at lunch and dinner.
After 12 weeks, the participants in the whey protein group lost the most weight (7.6 kg vs. 6.1 kg for participants in the high-protein group and 3.5 kg for those in the high-carbohydrate group (p<0.0001).
Participants on the whey protein diet were less hungry during the day and had lower glucose spikes after meals compared with those on the other two diets.
The drop in HbA1C was 11.5% in the whey group, 7.7% in the protein group and 4.6% in the carbohydrate group (p<0.0001). Compared with the carbohydrate group, the percentage drop in HbA1c was greater by 41% in the protein group and by 64% in the whey group (p<0.0001).
"Whey protein was consumed only at breakfast; however, the improvement of glucose, insulin and glucagon-like peptide 1 (GLP-1) was also observed after lunch and dinner. The mechanism of this persistent beneficial effect of whey protein needs further research," Dr. Jakubowicz said.
Co-author Dr. Julio Wainstein, also at Wolfson Medical Center, added by email, "Usually, patients with type 2 diabetes are treated with a combination of several antidiabetic drugs to achieve adequate glucose regulation and decrease HbA1c. Whey protein should be considered an important adjuvant in the management of type 2 diabetes."
"Furthermore," Dr. Wainstein added, "it is possible that by adding whey protein to the diet, glucose regulation might be achieved with less medication, which is a valuable advantage in type 2 diabetes treatment."
The study had no commercial funding, and the authors declared no conflicts of interest.
NEW YORK (Reuters Health) - A breakfast rich in whey protein may help people with type 2 diabetes manage their illness better, new research from Israel suggests.
"Whey protein, a byproduct of cheese manufacturing, lowers postprandial glycemia more than other protein sources," said lead author Dr. Daniela Jakubowicz from Wolfson Medical Center at Tel Aviv University."
We found that in type 2 diabetes, increasing protein content at breakfast has a greater impact on weight loss, glycated hemoglobin (HbA1C), satiety and postprandial glycemia when the protein source is whey protein, compared with other protein sources, such as eggs, tuna and soy," she told Reuters Health by email.
Dr. Jakubowicz and her group presented their findings April 1 at ENDO 2016, the annual meeting of the Endocrine Society, in Boston.
They randomly assigned 48 overweight and obese patients with type 2 diabetes to one of three isocaloric diets. Over 12 weeks, everyone ate a large breakfast, a medium-sized lunch and a small dinner, but the amount and source of each group's breakfast proteins differed.
At breakfast, the 17 participants in the whey group ate 36 g of protein as part of a whey protein shake consisting of 40% carbohydrate, 40% protein and 20% fat. The 16 participants in the high-protein group ate 36 g of protein in the form of eggs, tuna and cheese (40% carbs; 40% protein; 20% fat). The 15 in the high-carbohydrate group ate 13 g of protein in ready-to-eat cereals (65% carbs; 15% protein; 20% fat).
All three diets included a 660 kcal breakfast, a 567 cal lunch and a 276 cal dinner, with the same composition at lunch and dinner.
After 12 weeks, the participants in the whey protein group lost the most weight (7.6 kg vs. 6.1 kg for participants in the high-protein group and 3.5 kg for those in the high-carbohydrate group (p<0.0001).
Participants on the whey protein diet were less hungry during the day and had lower glucose spikes after meals compared with those on the other two diets.
The drop in HbA1C was 11.5% in the whey group, 7.7% in the protein group and 4.6% in the carbohydrate group (p<0.0001). Compared with the carbohydrate group, the percentage drop in HbA1c was greater by 41% in the protein group and by 64% in the whey group (p<0.0001).
"Whey protein was consumed only at breakfast; however, the improvement of glucose, insulin and glucagon-like peptide 1 (GLP-1) was also observed after lunch and dinner. The mechanism of this persistent beneficial effect of whey protein needs further research," Dr. Jakubowicz said.
Co-author Dr. Julio Wainstein, also at Wolfson Medical Center, added by email, "Usually, patients with type 2 diabetes are treated with a combination of several antidiabetic drugs to achieve adequate glucose regulation and decrease HbA1c. Whey protein should be considered an important adjuvant in the management of type 2 diabetes."
"Furthermore," Dr. Wainstein added, "it is possible that by adding whey protein to the diet, glucose regulation might be achieved with less medication, which is a valuable advantage in type 2 diabetes treatment."
The study had no commercial funding, and the authors declared no conflicts of interest.
Combo could improve treatment of MM, team says
multiple myeloma
Combining a calcineurin inhibitor and a histone deacetylase (HDAC) inhibitor could improve the treatment of multiple myeloma (MM), according to researchers.
The team found that MM cells express high levels of the protein phosphatase PPP3CA, a subunit of calcineurin.
And combining the calcineurin inhibitor FK506 with the HDAC inhibitor panobinostat suppressed MM cell growth in vitro and decreased tumor growth in mouse models of MM.
Yoichi Imai, MD, PhD, of Tokyo Women’s Medical University in Japan, and colleagues conducted this research and reported the results in JCI Insight.
First, the team observed increased PPP3CA expression in MM cell lines and MM cells isolated from patients with advanced disease.
Then, the researchers found that panobinostat reduced PPP3CA expression in MM cell lines. And further investigation revealed that the drug induced degradation of PPP3CA through HSP90 inhibition.
When the team knocked down PPP3CA in MM cells, they observed a reduction in cell growth. And when they overexpressed PPP3CA, they observed enhanced MM cell growth.
The researchers noted that FK506 inhibits the association between PPP3CA and calcineurin B. Unfortunately, FK506 alone did not suppress the growth of MM cells in vitro.
However, when FK506 was given with panobinostat or the HDAC inhibitor ACY-1215, the researchers observed a greater reduction in MM cell growth than with either HDAC inhibitor alone.
Panobinostat and FK506 reduced the growth of MM cells that were t(4;14)-positive (KMS-11, KMS-18, and KMS-26) and t(4;14)-negative (U266 and KMS-12PE) more effectively than panobinostat alone.
In mice with MM, those treated with FK506 alone had tumor sizes similar to control mice. However, mice treated with panobinostat saw a decrease in tumor size. And this effect was enhanced by the addition of FK506.
The researchers observed reduced PPP3CA expression, enhanced histone H3 acetylation, and cleavage of caspase-3 in samples from panobinostat-treated mice. And FK506 augmented panobinostat-induced apoptosis.
The team said these results suggest that FK506 enhances the antimyeloma effect of panobinostat through PPP3CA reduction, which supports the importance of calcineurin in the pathogenesis of MM. 
multiple myeloma
Combining a calcineurin inhibitor and a histone deacetylase (HDAC) inhibitor could improve the treatment of multiple myeloma (MM), according to researchers.
The team found that MM cells express high levels of the protein phosphatase PPP3CA, a subunit of calcineurin.
And combining the calcineurin inhibitor FK506 with the HDAC inhibitor panobinostat suppressed MM cell growth in vitro and decreased tumor growth in mouse models of MM.
Yoichi Imai, MD, PhD, of Tokyo Women’s Medical University in Japan, and colleagues conducted this research and reported the results in JCI Insight.
First, the team observed increased PPP3CA expression in MM cell lines and MM cells isolated from patients with advanced disease.
Then, the researchers found that panobinostat reduced PPP3CA expression in MM cell lines. And further investigation revealed that the drug induced degradation of PPP3CA through HSP90 inhibition.
When the team knocked down PPP3CA in MM cells, they observed a reduction in cell growth. And when they overexpressed PPP3CA, they observed enhanced MM cell growth.
The researchers noted that FK506 inhibits the association between PPP3CA and calcineurin B. Unfortunately, FK506 alone did not suppress the growth of MM cells in vitro.
However, when FK506 was given with panobinostat or the HDAC inhibitor ACY-1215, the researchers observed a greater reduction in MM cell growth than with either HDAC inhibitor alone.
Panobinostat and FK506 reduced the growth of MM cells that were t(4;14)-positive (KMS-11, KMS-18, and KMS-26) and t(4;14)-negative (U266 and KMS-12PE) more effectively than panobinostat alone.
In mice with MM, those treated with FK506 alone had tumor sizes similar to control mice. However, mice treated with panobinostat saw a decrease in tumor size. And this effect was enhanced by the addition of FK506.
The researchers observed reduced PPP3CA expression, enhanced histone H3 acetylation, and cleavage of caspase-3 in samples from panobinostat-treated mice. And FK506 augmented panobinostat-induced apoptosis.
The team said these results suggest that FK506 enhances the antimyeloma effect of panobinostat through PPP3CA reduction, which supports the importance of calcineurin in the pathogenesis of MM.
multiple myeloma
Combining a calcineurin inhibitor and a histone deacetylase (HDAC) inhibitor could improve the treatment of multiple myeloma (MM), according to researchers.
The team found that MM cells express high levels of the protein phosphatase PPP3CA, a subunit of calcineurin.
And combining the calcineurin inhibitor FK506 with the HDAC inhibitor panobinostat suppressed MM cell growth in vitro and decreased tumor growth in mouse models of MM.
Yoichi Imai, MD, PhD, of Tokyo Women’s Medical University in Japan, and colleagues conducted this research and reported the results in JCI Insight.
First, the team observed increased PPP3CA expression in MM cell lines and MM cells isolated from patients with advanced disease.
Then, the researchers found that panobinostat reduced PPP3CA expression in MM cell lines. And further investigation revealed that the drug induced degradation of PPP3CA through HSP90 inhibition.
When the team knocked down PPP3CA in MM cells, they observed a reduction in cell growth. And when they overexpressed PPP3CA, they observed enhanced MM cell growth.
The researchers noted that FK506 inhibits the association between PPP3CA and calcineurin B. Unfortunately, FK506 alone did not suppress the growth of MM cells in vitro.
However, when FK506 was given with panobinostat or the HDAC inhibitor ACY-1215, the researchers observed a greater reduction in MM cell growth than with either HDAC inhibitor alone.
Panobinostat and FK506 reduced the growth of MM cells that were t(4;14)-positive (KMS-11, KMS-18, and KMS-26) and t(4;14)-negative (U266 and KMS-12PE) more effectively than panobinostat alone.
In mice with MM, those treated with FK506 alone had tumor sizes similar to control mice. However, mice treated with panobinostat saw a decrease in tumor size. And this effect was enhanced by the addition of FK506.
The researchers observed reduced PPP3CA expression, enhanced histone H3 acetylation, and cleavage of caspase-3 in samples from panobinostat-treated mice. And FK506 augmented panobinostat-induced apoptosis.
The team said these results suggest that FK506 enhances the antimyeloma effect of panobinostat through PPP3CA reduction, which supports the importance of calcineurin in the pathogenesis of MM.
Drug corrects anemia in CKD patients
The investigational therapy roxadustat can effectively treat anemia in patients with chronic kidney disease (CKD) who are not on dialysis, according to a phase 2 study.
Roxadustat increased and maintained hemoglobin levels and decreased hepcidin levels in these patients, who had not received previous treatment with
erythropoiesis-stimulating agents and were treated with roxadustat regardless of their baseline iron repletion status.
In addition, researchers said there were no serious adverse events related to roxadustat.
Robert Provenzano, MD, of St. John Hospital and Medical Center in Detroit, Michigan, and his colleagues reported these results in the Clinical Journal of the American Society of Nephrology.
The study was sponsored by FibroGen, Inc., the company developing roxadustat in collaboration with AstraZeneca.
Roxadustat (FG-4592) is an oral, small-molecule inhibitor of hypoxia-inducible factor (HIF) prolyl hydroxylase activity. HIF is a transcription factor that induces the natural physiological response to conditions of low oxygen, “turning on” erythropoiesis and other protective pathways.
In this randomized, phase 2 study of roxadustat, 145 patients with anemia (hemoglobin < 10.5 g/dL at baseline) and non-dialysis CKD were randomized into 1 of 6 cohorts of approximately 24 patients.
The cohorts had varying roxadustat starting doses (tiered weight and fixed amounts) and frequencies (2 and 3 times weekly), followed by hemoglobin maintenance with roxadustat 1 to 3 times weekly. The treatment duration was 16 or 24 weeks.
Results
Of the 143 patients evaluable for efficacy, 92% achieved a hemoglobin response—defined as a hemoglobin increase of > 1.0 g/dL from baseline and a hemoglobin of > 11.0 g/dL by the end of treatment (up to 16 weeks of treatment in 47 patients, and up to 24 weeks of treatment in 96 patients).
Generally, patients in all cohorts who received higher starting doses of roxadustat demonstrated earlier achievement of the hemoglobin response.
Roxadustat increased hemoglobin independently of the patients’ baseline iron repletion and inflammatory status, as measured by baseline C–reactive protein levels. Intravenous iron was not permitted throughout the study period, and 52.4% of patients were iron-replete at baseline.
Over 16 weeks of treatment, roxadustat decreased hepcidin levels by 16.9% (P=0.004), maintained reticulocyte hemoglobin content, and increased hemoglobin by a mean (±SD) of 1.83 (±0.09) g/dL (P<0.001).
After 8 weeks of roxadustat, total cholesterol levels decreased by a mean (±SD) of 26 (±30) mg/dL (P<0.001).
“In this study, anemia correction was achieved under a range of treatment options, including tiered-weight as well as fixed-starting-dose strategies,” Dr Provenzano said. “Correction of anemia and maintenance of hemoglobin response were seen at different dose frequencies—2 or 3 times weekly for achievement of hemoglobin response; 1, 2, or 3 times weekly for maintenance.”
“Secondary analyses showing decreases in hepcidin and increased iron utilization, as well as reductions in total cholesterol levels, suggest roxadustat consistently affects these parameters.”
Treatment-emergent adverse events were reported in 80% of all patients.
The most common events that occurred in more than 5% of patients were nausea (9.7%), diarrhea (8.3%), constipation (6.2%), vomiting (5.5%), peripheral edema (12.4%), urinary tract infection (9.7%), nasopharyngitis (9.0%), sinusitis (5.5%), dizziness (6.2%), headache (5.5%), and hypertension (7.6%).
The investigational therapy roxadustat can effectively treat anemia in patients with chronic kidney disease (CKD) who are not on dialysis, according to a phase 2 study.
Roxadustat increased and maintained hemoglobin levels and decreased hepcidin levels in these patients, who had not received previous treatment with
erythropoiesis-stimulating agents and were treated with roxadustat regardless of their baseline iron repletion status.
In addition, researchers said there were no serious adverse events related to roxadustat.
Robert Provenzano, MD, of St. John Hospital and Medical Center in Detroit, Michigan, and his colleagues reported these results in the Clinical Journal of the American Society of Nephrology.
The study was sponsored by FibroGen, Inc., the company developing roxadustat in collaboration with AstraZeneca.
Roxadustat (FG-4592) is an oral, small-molecule inhibitor of hypoxia-inducible factor (HIF) prolyl hydroxylase activity. HIF is a transcription factor that induces the natural physiological response to conditions of low oxygen, “turning on” erythropoiesis and other protective pathways.
In this randomized, phase 2 study of roxadustat, 145 patients with anemia (hemoglobin < 10.5 g/dL at baseline) and non-dialysis CKD were randomized into 1 of 6 cohorts of approximately 24 patients.
The cohorts had varying roxadustat starting doses (tiered weight and fixed amounts) and frequencies (2 and 3 times weekly), followed by hemoglobin maintenance with roxadustat 1 to 3 times weekly. The treatment duration was 16 or 24 weeks.
Results
Of the 143 patients evaluable for efficacy, 92% achieved a hemoglobin response—defined as a hemoglobin increase of > 1.0 g/dL from baseline and a hemoglobin of > 11.0 g/dL by the end of treatment (up to 16 weeks of treatment in 47 patients, and up to 24 weeks of treatment in 96 patients).
Generally, patients in all cohorts who received higher starting doses of roxadustat demonstrated earlier achievement of the hemoglobin response.
Roxadustat increased hemoglobin independently of the patients’ baseline iron repletion and inflammatory status, as measured by baseline C–reactive protein levels. Intravenous iron was not permitted throughout the study period, and 52.4% of patients were iron-replete at baseline.
Over 16 weeks of treatment, roxadustat decreased hepcidin levels by 16.9% (P=0.004), maintained reticulocyte hemoglobin content, and increased hemoglobin by a mean (±SD) of 1.83 (±0.09) g/dL (P<0.001).
After 8 weeks of roxadustat, total cholesterol levels decreased by a mean (±SD) of 26 (±30) mg/dL (P<0.001).
“In this study, anemia correction was achieved under a range of treatment options, including tiered-weight as well as fixed-starting-dose strategies,” Dr Provenzano said. “Correction of anemia and maintenance of hemoglobin response were seen at different dose frequencies—2 or 3 times weekly for achievement of hemoglobin response; 1, 2, or 3 times weekly for maintenance.”
“Secondary analyses showing decreases in hepcidin and increased iron utilization, as well as reductions in total cholesterol levels, suggest roxadustat consistently affects these parameters.”
Treatment-emergent adverse events were reported in 80% of all patients.
The most common events that occurred in more than 5% of patients were nausea (9.7%), diarrhea (8.3%), constipation (6.2%), vomiting (5.5%), peripheral edema (12.4%), urinary tract infection (9.7%), nasopharyngitis (9.0%), sinusitis (5.5%), dizziness (6.2%), headache (5.5%), and hypertension (7.6%).
The investigational therapy roxadustat can effectively treat anemia in patients with chronic kidney disease (CKD) who are not on dialysis, according to a phase 2 study.
Roxadustat increased and maintained hemoglobin levels and decreased hepcidin levels in these patients, who had not received previous treatment with
erythropoiesis-stimulating agents and were treated with roxadustat regardless of their baseline iron repletion status.
In addition, researchers said there were no serious adverse events related to roxadustat.
Robert Provenzano, MD, of St. John Hospital and Medical Center in Detroit, Michigan, and his colleagues reported these results in the Clinical Journal of the American Society of Nephrology.
The study was sponsored by FibroGen, Inc., the company developing roxadustat in collaboration with AstraZeneca.
Roxadustat (FG-4592) is an oral, small-molecule inhibitor of hypoxia-inducible factor (HIF) prolyl hydroxylase activity. HIF is a transcription factor that induces the natural physiological response to conditions of low oxygen, “turning on” erythropoiesis and other protective pathways.
In this randomized, phase 2 study of roxadustat, 145 patients with anemia (hemoglobin < 10.5 g/dL at baseline) and non-dialysis CKD were randomized into 1 of 6 cohorts of approximately 24 patients.
The cohorts had varying roxadustat starting doses (tiered weight and fixed amounts) and frequencies (2 and 3 times weekly), followed by hemoglobin maintenance with roxadustat 1 to 3 times weekly. The treatment duration was 16 or 24 weeks.
Results
Of the 143 patients evaluable for efficacy, 92% achieved a hemoglobin response—defined as a hemoglobin increase of > 1.0 g/dL from baseline and a hemoglobin of > 11.0 g/dL by the end of treatment (up to 16 weeks of treatment in 47 patients, and up to 24 weeks of treatment in 96 patients).
Generally, patients in all cohorts who received higher starting doses of roxadustat demonstrated earlier achievement of the hemoglobin response.
Roxadustat increased hemoglobin independently of the patients’ baseline iron repletion and inflammatory status, as measured by baseline C–reactive protein levels. Intravenous iron was not permitted throughout the study period, and 52.4% of patients were iron-replete at baseline.
Over 16 weeks of treatment, roxadustat decreased hepcidin levels by 16.9% (P=0.004), maintained reticulocyte hemoglobin content, and increased hemoglobin by a mean (±SD) of 1.83 (±0.09) g/dL (P<0.001).
After 8 weeks of roxadustat, total cholesterol levels decreased by a mean (±SD) of 26 (±30) mg/dL (P<0.001).
“In this study, anemia correction was achieved under a range of treatment options, including tiered-weight as well as fixed-starting-dose strategies,” Dr Provenzano said. “Correction of anemia and maintenance of hemoglobin response were seen at different dose frequencies—2 or 3 times weekly for achievement of hemoglobin response; 1, 2, or 3 times weekly for maintenance.”
“Secondary analyses showing decreases in hepcidin and increased iron utilization, as well as reductions in total cholesterol levels, suggest roxadustat consistently affects these parameters.”
Treatment-emergent adverse events were reported in 80% of all patients.
The most common events that occurred in more than 5% of patients were nausea (9.7%), diarrhea (8.3%), constipation (6.2%), vomiting (5.5%), peripheral edema (12.4%), urinary tract infection (9.7%), nasopharyngitis (9.0%), sinusitis (5.5%), dizziness (6.2%), headache (5.5%), and hypertension (7.6%).
A valuable string of PURLs
Since JFP’s launch of the PURL department in November of 2007, 122 PURLs—Priority Updates from the Research Literature—have been published. The Journal of Family Practice is the exclusive publication venue for these items. Because they have stood the test of time and are one of the more popular columns in JFP, I thought it would be worthwhile to describe the rigorous evaluation they undergo before they are published.
Many studies, but few PURLs. Each year, approximately 200,000 new human medical research studies are indexed on PubMed. Very few of these studies are pertinent to family medicine, however, and even fewer provide new patient-oriented evidence for primary care clinicians.
In 2005, the leaders of the Family Physician Inquiries Network (FPIN), which produces another popular JFP column, Clinical Inquiries, set about identifying high-priority research findings relevant to family medicine. A group of family physicians and librarians began combing the research literature monthly to find those rare randomized trials or high-quality observational studies that pertained to our specialty. To qualify as a PURL, a study had to meet 6 criteria. It had to be scientifically valid, relevant to family medicine, applicable in a medical care setting, immediately implementable, clinically meaningful, and practice changing. These criteria still stand today.
Making the cut. When a study is identified as a potential PURL, it is submitted to one of FPIN’s PURL review groups for a critical appraisal and rigorous peer review. If the group cannot convince the PURLs editors that the original research meets all 6 criteria, the study falls by the wayside. Most potential PURLs do not make the cut. I was one of the early PURL “divers,” and I was amazed at how few PURLs existed. Given the emphasis of research on subspecialties and the dearth of primary care research funding in the United States, I probably shouldn’t have been surprised.
Holding their value. I reviewed all 122 PURLs this week and am proud to say that nearly all still provide highly pertinent, practice-changing information for family physicians and other primary care clinicians. For a quick review of our string of PURLs, go to www.jfponline.com, select “Articles” in the banner, and then “PURLs,” and read the short practice changer box for each one. I guarantee it will be time well spent!
If you would like to become part of the PURLs process, either by nominating or reviewing a PURL, please contact the PURLs Project Manager at [email protected].
Since JFP’s launch of the PURL department in November of 2007, 122 PURLs—Priority Updates from the Research Literature—have been published. The Journal of Family Practice is the exclusive publication venue for these items. Because they have stood the test of time and are one of the more popular columns in JFP, I thought it would be worthwhile to describe the rigorous evaluation they undergo before they are published.
Many studies, but few PURLs. Each year, approximately 200,000 new human medical research studies are indexed on PubMed. Very few of these studies are pertinent to family medicine, however, and even fewer provide new patient-oriented evidence for primary care clinicians.
In 2005, the leaders of the Family Physician Inquiries Network (FPIN), which produces another popular JFP column, Clinical Inquiries, set about identifying high-priority research findings relevant to family medicine. A group of family physicians and librarians began combing the research literature monthly to find those rare randomized trials or high-quality observational studies that pertained to our specialty. To qualify as a PURL, a study had to meet 6 criteria. It had to be scientifically valid, relevant to family medicine, applicable in a medical care setting, immediately implementable, clinically meaningful, and practice changing. These criteria still stand today.
Making the cut. When a study is identified as a potential PURL, it is submitted to one of FPIN’s PURL review groups for a critical appraisal and rigorous peer review. If the group cannot convince the PURLs editors that the original research meets all 6 criteria, the study falls by the wayside. Most potential PURLs do not make the cut. I was one of the early PURL “divers,” and I was amazed at how few PURLs existed. Given the emphasis of research on subspecialties and the dearth of primary care research funding in the United States, I probably shouldn’t have been surprised.
Holding their value. I reviewed all 122 PURLs this week and am proud to say that nearly all still provide highly pertinent, practice-changing information for family physicians and other primary care clinicians. For a quick review of our string of PURLs, go to www.jfponline.com, select “Articles” in the banner, and then “PURLs,” and read the short practice changer box for each one. I guarantee it will be time well spent!
If you would like to become part of the PURLs process, either by nominating or reviewing a PURL, please contact the PURLs Project Manager at [email protected].
Since JFP’s launch of the PURL department in November of 2007, 122 PURLs—Priority Updates from the Research Literature—have been published. The Journal of Family Practice is the exclusive publication venue for these items. Because they have stood the test of time and are one of the more popular columns in JFP, I thought it would be worthwhile to describe the rigorous evaluation they undergo before they are published.
Many studies, but few PURLs. Each year, approximately 200,000 new human medical research studies are indexed on PubMed. Very few of these studies are pertinent to family medicine, however, and even fewer provide new patient-oriented evidence for primary care clinicians.
In 2005, the leaders of the Family Physician Inquiries Network (FPIN), which produces another popular JFP column, Clinical Inquiries, set about identifying high-priority research findings relevant to family medicine. A group of family physicians and librarians began combing the research literature monthly to find those rare randomized trials or high-quality observational studies that pertained to our specialty. To qualify as a PURL, a study had to meet 6 criteria. It had to be scientifically valid, relevant to family medicine, applicable in a medical care setting, immediately implementable, clinically meaningful, and practice changing. These criteria still stand today.
Making the cut. When a study is identified as a potential PURL, it is submitted to one of FPIN’s PURL review groups for a critical appraisal and rigorous peer review. If the group cannot convince the PURLs editors that the original research meets all 6 criteria, the study falls by the wayside. Most potential PURLs do not make the cut. I was one of the early PURL “divers,” and I was amazed at how few PURLs existed. Given the emphasis of research on subspecialties and the dearth of primary care research funding in the United States, I probably shouldn’t have been surprised.
Holding their value. I reviewed all 122 PURLs this week and am proud to say that nearly all still provide highly pertinent, practice-changing information for family physicians and other primary care clinicians. For a quick review of our string of PURLs, go to www.jfponline.com, select “Articles” in the banner, and then “PURLs,” and read the short practice changer box for each one. I guarantee it will be time well spent!
If you would like to become part of the PURLs process, either by nominating or reviewing a PURL, please contact the PURLs Project Manager at [email protected].
Increased syncopal episodes post surgery • Dx?
THE CASE
A 58-year-old woman sought care at our clinic for recurrent syncopal and near-syncopal events following surgical repair of a left hip fracture. The first syncopal event occurred one day post-surgery shortly after standing and was attributed to orthostatic hypotension. Subsequently, the patient experienced 2 events during her hospital stay. Both events occurred in the upright position and were preceded by lightheadedness, warmth, and diaphoresis. They were short in duration (<30 seconds) with spontaneous and complete recovery. The patient had no associated chest pain or palpitations.
The patient’s past medical history included osteopenia, dyslipidemia, and vasovagal syncope, averaging one to 2 events per year. Given her past history, the physicians caring for her assumed that she was having recurrences of her vasovagal syncope. She was discharged home on fludrocortisone 0.1 mg/d, sodium chloride 1 g tid, enoxaparin 40 mg/d, and acetaminophen and oxycodone as needed for pain.
One week later, the patient experienced another syncopal event at home, prompting her to visit our clinic for further evaluation. On arrival, her vital signs were stable. Her oxygen saturation level was 98%, she was not orthostatic, and her physical exam and blood studies were unremarkable. An echocardiogram showed preserved left ventricular function with no evidence of right ventricular dilatation or strain.
THE DIAGNOSIS
The patient’s revised Geneva Score for pulmonary embolism (PE) was 2 to 5 depending on the heart rate used (66-80 beats per minute), putting her in a low-to-intermediate risk group with an estimated PE prevalence between 8% and 28%.1 Given her recent surgery and the increase in the frequency of her vasovagal events, a computed tomography pulmonary angiogram (CT-PA) was performed. The CT-PA showed a PE in the lateral and posterior basal subsegmental branches of the right lower lobe. Doppler ultrasound revealed no evidence of acute deep vein thrombosis.
DISCUSSION
Syncope may develop in 9% to 19% of patients with PE.2-6 While syncope in patients with PE is often attributed to reduced cardiac filling secondary to massive emboli, it is important to recognize that patients can also present with vasovagal syncope in the absence of massive emboli.
One mechanism for the development of syncope is right ventricular failure with subsequent impairment of left ventricular filling, leading to arterial hypotension. Indeed, the majority of patients with PE and syncope have a massive embolism defined as greater than a 50% reduction in the pulmonary circulation.7 In one study, 60% of patients with PE who presented with syncope had a massive PE compared to 39% of patients presenting without syncope (P=.036).8
Another reported mechanism for syncope in a patient with PE is transient high-degree atrioventricular (AV) block.9 Sudden increases in right-sided pressure can lead to transient right bundle branch block, which may result in complete heart block in the setting of baseline left bundle branch block.
Lastly, patients with PE may develop a vasovagal-like reaction, such as the Bezold-Jarisch reflex, which results in transient arterial hypotension and cerebral hypoperfusion.10 In such instances, the postulated mechanism is activation of cardiac vagal afferents, which results in an increase in vagal tone and peripheral sympathetic withdrawal leading to hypotension and syncope. It is important to note that this mechanism can occur in the absence of massive PE. In one study, up to 40% of patients with PE and syncope did not have a massive PE, and almost 6% had thrombi only in small branches of the pulmonary artery.8
This patient had isolated subsegmental defects, identified on the CT-PA. The sensitivity of CT-PA to detect subsegmental PE ranges from 53% to 100%.11 While this test has its limitations, the introduction of the multi-detector CT technique has significantly increased the rate of detection with a specificity of 96%.12,13
Was PE the cause of the syncope, or just an incidental finding?
In this case, we believe the CT-PA findings were diagnostic for PE. What is less clear is whether the PE was the cause of the syncope.
Asymptomatic post-operative PE with isolated subsegmental defects has been reported.14-16 When compared to patients with a defect at a segmental or more proximal level, these patients often have less dyspnea, are less likely to be classified as having a high clinical probability of PE, and have a lower prevalence of proximal deep vein thrombosis (3.3% vs 43.8%; P<.0001).17 Therefore, one could argue that the PE finding in our case was incidental. While this is a possibility, we believe the patient’s syncope was due to PE for the following reasons.
First, several investigators have reported transient increases in vagal tone and syncope following PE consistent with a vasovagal-like response.7,18 Therefore, it is possible that the reduction in preload associated with PE triggered a Bezold-Jarisch-like reflex leading to syncope. The patient’s history of vasovagal syncope was certainly indicative of increased susceptibility to reflex-mediated events, thus supporting our hypothesis.
Second, our patient had a cluster of events following surgery compared to the one to 2 events she experienced per year prior to surgery. The increased incidence of events would be an unusual progression of her syncope in the absence of clear triggers, again rendering our hypothesis more plausible.
The patient was admitted to our hospital and started on a higher dose of enoxaparin (60 mg twice daily). She was subsequently discharged home on rivaroxaban 15 mg twice daily and midodrine 2.5 mg twice daily in addition to the medications she was already taking. At her 6-week follow-up visit, she reported no recurrences.
THE TAKEAWAY
This case demonstrates that non-massive PE can present as vasovagal syncope. Recognizing that PE could lead to reflex-mediated syncope in the absence of massive emboli, it is important to rule it out in the evaluation of patients with vasovagal syncope when risk factors for PE are present.
1. Le Gal G, Righini M, Roy PM, et al. Prediction of pulmonary embolism in the emergency department: the revised Geneva score. Ann Intern Med. 2006;144:165-171.
2. Calvo-Romero JM, Pérez-Miranda M, Bureo-Dacal P. Syncope in acute pulmonary embolism. Eur J Emerg Med. 2004;11:208-209.
3. Castelli R, Tarsia P, Tantardini C, et al. Syncope in patients with pulmonary embolism: comparison between patients with syncope as the presenting symptom of pulmonary embolism and patients with pulmonary embolism without syncope. Vasc Med. 2003;8:257-261.
4. Kasper W, Konstantinides S, Geibel A, et al. Management strategies and determinants of outcome in acute major pulmonary embolism: results of a multicenter registry. J Am Coll Cardiol. 1997;30:1165-1171.
5. Koutkia P, Wachtel TJ. Pulmonary embolism presenting as syncope: case report and review of the literature. Heart Lung. 1999;28:342-347.
6. Torbicki A, Perrier A, Konstantinides S, et al; ESC Committee for Practice Guidelines (CPG). Guidelines on the diagnosis and management of acute pulmonary embolism: the Task Force for the Diagnosis and Management of Acute Pulmonary Embolism of the European Society of Cardiology (ESC). Eur Heart J. 2008;29:2276-2315.
7. Thames MD, Alpert JS, Dalen JE. Syncope in patients with pulmonary embolism. JAMA. 1977;238:2509-2511.
8. Duplyakov D, Kurakina E, Pavlova T, et al. Value of syncope in patients with high-to-intermediate risk pulmonary artery embolism. Eur Heart J Acute Cardiovasc Care. 2015;4:353-358.
9. Wilner C, Garnier-Crussard JP, Huygue De Mahenge A, et al. [Paroxysmal atrioventricular block, cause of syncope in pulmonary embolism. 2 cases]. Presse Med. 1983;12:2987-2989.
10. Frink RJ, James TN. Intracardiac route of the Bezold-Jarisch reflex. Am J Physiol. 1971;221:1464-1469.
11. Rathbun SW, Raskob GE, Whitsett TL. Sensitivity and specificity of helical computed tomography in the diagnosis of pulmonary embolism: A systematic review. Ann Intern Med. 2000;132:227-232.
12. Stein PD, Fowler SE, Goodman LR, et al; PIOPED II Investigators. Multidetector computed tomography for acute pulmonary embolism. N Engl J Med. 2006;354:2317-2327.
13. Vedovati MC, Becattini C, Agnelli G, et al. Multidetector CT scan for acute pulmonary embolism: embolic burden and clinical outcome. Chest. 2012;142:1417-1424.
14. Musset D, Parent F, Meyer G, et al; Evaluation du Scanner Spiralé dans l’Embolie Pulmonaire study group. Diagnostic strategy for patients with suspected pulmonary embolism: a prospective multicentre outcome study. Lancet. 2002;360:1914-1920.
15. Simpson RJ Jr, Podolak R, Mangano CA Jr, et al. Vagal syncope during recurrent pulmonary embolism. JAMA. 1983;249:390-393.
16. Perrier A, Roy PM, Sanchez O, et al. Multidetector-row computed tomography in suspected pulmonary embolism. N Engl J Med. 2005;352:1760-1768.
17. Le Gal G, Righini M, Parent F, et al. Diagnosis and management of subsegmental pulmonary embolism. J Thromb Haemost. 2006;4:724-731.
18. Eldadah ZA, Najjar SS, Ziegelstein RC. A patient with syncope, only “vagally” related to the heart. Chest. 2000;117:1801-1803.
THE CASE
A 58-year-old woman sought care at our clinic for recurrent syncopal and near-syncopal events following surgical repair of a left hip fracture. The first syncopal event occurred one day post-surgery shortly after standing and was attributed to orthostatic hypotension. Subsequently, the patient experienced 2 events during her hospital stay. Both events occurred in the upright position and were preceded by lightheadedness, warmth, and diaphoresis. They were short in duration (<30 seconds) with spontaneous and complete recovery. The patient had no associated chest pain or palpitations.
The patient’s past medical history included osteopenia, dyslipidemia, and vasovagal syncope, averaging one to 2 events per year. Given her past history, the physicians caring for her assumed that she was having recurrences of her vasovagal syncope. She was discharged home on fludrocortisone 0.1 mg/d, sodium chloride 1 g tid, enoxaparin 40 mg/d, and acetaminophen and oxycodone as needed for pain.
One week later, the patient experienced another syncopal event at home, prompting her to visit our clinic for further evaluation. On arrival, her vital signs were stable. Her oxygen saturation level was 98%, she was not orthostatic, and her physical exam and blood studies were unremarkable. An echocardiogram showed preserved left ventricular function with no evidence of right ventricular dilatation or strain.
THE DIAGNOSIS
The patient’s revised Geneva Score for pulmonary embolism (PE) was 2 to 5 depending on the heart rate used (66-80 beats per minute), putting her in a low-to-intermediate risk group with an estimated PE prevalence between 8% and 28%.1 Given her recent surgery and the increase in the frequency of her vasovagal events, a computed tomography pulmonary angiogram (CT-PA) was performed. The CT-PA showed a PE in the lateral and posterior basal subsegmental branches of the right lower lobe. Doppler ultrasound revealed no evidence of acute deep vein thrombosis.
DISCUSSION
Syncope may develop in 9% to 19% of patients with PE.2-6 While syncope in patients with PE is often attributed to reduced cardiac filling secondary to massive emboli, it is important to recognize that patients can also present with vasovagal syncope in the absence of massive emboli.
One mechanism for the development of syncope is right ventricular failure with subsequent impairment of left ventricular filling, leading to arterial hypotension. Indeed, the majority of patients with PE and syncope have a massive embolism defined as greater than a 50% reduction in the pulmonary circulation.7 In one study, 60% of patients with PE who presented with syncope had a massive PE compared to 39% of patients presenting without syncope (P=.036).8
Another reported mechanism for syncope in a patient with PE is transient high-degree atrioventricular (AV) block.9 Sudden increases in right-sided pressure can lead to transient right bundle branch block, which may result in complete heart block in the setting of baseline left bundle branch block.
Lastly, patients with PE may develop a vasovagal-like reaction, such as the Bezold-Jarisch reflex, which results in transient arterial hypotension and cerebral hypoperfusion.10 In such instances, the postulated mechanism is activation of cardiac vagal afferents, which results in an increase in vagal tone and peripheral sympathetic withdrawal leading to hypotension and syncope. It is important to note that this mechanism can occur in the absence of massive PE. In one study, up to 40% of patients with PE and syncope did not have a massive PE, and almost 6% had thrombi only in small branches of the pulmonary artery.8
This patient had isolated subsegmental defects, identified on the CT-PA. The sensitivity of CT-PA to detect subsegmental PE ranges from 53% to 100%.11 While this test has its limitations, the introduction of the multi-detector CT technique has significantly increased the rate of detection with a specificity of 96%.12,13
Was PE the cause of the syncope, or just an incidental finding?
In this case, we believe the CT-PA findings were diagnostic for PE. What is less clear is whether the PE was the cause of the syncope.
Asymptomatic post-operative PE with isolated subsegmental defects has been reported.14-16 When compared to patients with a defect at a segmental or more proximal level, these patients often have less dyspnea, are less likely to be classified as having a high clinical probability of PE, and have a lower prevalence of proximal deep vein thrombosis (3.3% vs 43.8%; P<.0001).17 Therefore, one could argue that the PE finding in our case was incidental. While this is a possibility, we believe the patient’s syncope was due to PE for the following reasons.
First, several investigators have reported transient increases in vagal tone and syncope following PE consistent with a vasovagal-like response.7,18 Therefore, it is possible that the reduction in preload associated with PE triggered a Bezold-Jarisch-like reflex leading to syncope. The patient’s history of vasovagal syncope was certainly indicative of increased susceptibility to reflex-mediated events, thus supporting our hypothesis.
Second, our patient had a cluster of events following surgery compared to the one to 2 events she experienced per year prior to surgery. The increased incidence of events would be an unusual progression of her syncope in the absence of clear triggers, again rendering our hypothesis more plausible.
The patient was admitted to our hospital and started on a higher dose of enoxaparin (60 mg twice daily). She was subsequently discharged home on rivaroxaban 15 mg twice daily and midodrine 2.5 mg twice daily in addition to the medications she was already taking. At her 6-week follow-up visit, she reported no recurrences.
THE TAKEAWAY
This case demonstrates that non-massive PE can present as vasovagal syncope. Recognizing that PE could lead to reflex-mediated syncope in the absence of massive emboli, it is important to rule it out in the evaluation of patients with vasovagal syncope when risk factors for PE are present.
THE CASE
A 58-year-old woman sought care at our clinic for recurrent syncopal and near-syncopal events following surgical repair of a left hip fracture. The first syncopal event occurred one day post-surgery shortly after standing and was attributed to orthostatic hypotension. Subsequently, the patient experienced 2 events during her hospital stay. Both events occurred in the upright position and were preceded by lightheadedness, warmth, and diaphoresis. They were short in duration (<30 seconds) with spontaneous and complete recovery. The patient had no associated chest pain or palpitations.
The patient’s past medical history included osteopenia, dyslipidemia, and vasovagal syncope, averaging one to 2 events per year. Given her past history, the physicians caring for her assumed that she was having recurrences of her vasovagal syncope. She was discharged home on fludrocortisone 0.1 mg/d, sodium chloride 1 g tid, enoxaparin 40 mg/d, and acetaminophen and oxycodone as needed for pain.
One week later, the patient experienced another syncopal event at home, prompting her to visit our clinic for further evaluation. On arrival, her vital signs were stable. Her oxygen saturation level was 98%, she was not orthostatic, and her physical exam and blood studies were unremarkable. An echocardiogram showed preserved left ventricular function with no evidence of right ventricular dilatation or strain.
THE DIAGNOSIS
The patient’s revised Geneva Score for pulmonary embolism (PE) was 2 to 5 depending on the heart rate used (66-80 beats per minute), putting her in a low-to-intermediate risk group with an estimated PE prevalence between 8% and 28%.1 Given her recent surgery and the increase in the frequency of her vasovagal events, a computed tomography pulmonary angiogram (CT-PA) was performed. The CT-PA showed a PE in the lateral and posterior basal subsegmental branches of the right lower lobe. Doppler ultrasound revealed no evidence of acute deep vein thrombosis.
DISCUSSION
Syncope may develop in 9% to 19% of patients with PE.2-6 While syncope in patients with PE is often attributed to reduced cardiac filling secondary to massive emboli, it is important to recognize that patients can also present with vasovagal syncope in the absence of massive emboli.
One mechanism for the development of syncope is right ventricular failure with subsequent impairment of left ventricular filling, leading to arterial hypotension. Indeed, the majority of patients with PE and syncope have a massive embolism defined as greater than a 50% reduction in the pulmonary circulation.7 In one study, 60% of patients with PE who presented with syncope had a massive PE compared to 39% of patients presenting without syncope (P=.036).8
Another reported mechanism for syncope in a patient with PE is transient high-degree atrioventricular (AV) block.9 Sudden increases in right-sided pressure can lead to transient right bundle branch block, which may result in complete heart block in the setting of baseline left bundle branch block.
Lastly, patients with PE may develop a vasovagal-like reaction, such as the Bezold-Jarisch reflex, which results in transient arterial hypotension and cerebral hypoperfusion.10 In such instances, the postulated mechanism is activation of cardiac vagal afferents, which results in an increase in vagal tone and peripheral sympathetic withdrawal leading to hypotension and syncope. It is important to note that this mechanism can occur in the absence of massive PE. In one study, up to 40% of patients with PE and syncope did not have a massive PE, and almost 6% had thrombi only in small branches of the pulmonary artery.8
This patient had isolated subsegmental defects, identified on the CT-PA. The sensitivity of CT-PA to detect subsegmental PE ranges from 53% to 100%.11 While this test has its limitations, the introduction of the multi-detector CT technique has significantly increased the rate of detection with a specificity of 96%.12,13
Was PE the cause of the syncope, or just an incidental finding?
In this case, we believe the CT-PA findings were diagnostic for PE. What is less clear is whether the PE was the cause of the syncope.
Asymptomatic post-operative PE with isolated subsegmental defects has been reported.14-16 When compared to patients with a defect at a segmental or more proximal level, these patients often have less dyspnea, are less likely to be classified as having a high clinical probability of PE, and have a lower prevalence of proximal deep vein thrombosis (3.3% vs 43.8%; P<.0001).17 Therefore, one could argue that the PE finding in our case was incidental. While this is a possibility, we believe the patient’s syncope was due to PE for the following reasons.
First, several investigators have reported transient increases in vagal tone and syncope following PE consistent with a vasovagal-like response.7,18 Therefore, it is possible that the reduction in preload associated with PE triggered a Bezold-Jarisch-like reflex leading to syncope. The patient’s history of vasovagal syncope was certainly indicative of increased susceptibility to reflex-mediated events, thus supporting our hypothesis.
Second, our patient had a cluster of events following surgery compared to the one to 2 events she experienced per year prior to surgery. The increased incidence of events would be an unusual progression of her syncope in the absence of clear triggers, again rendering our hypothesis more plausible.
The patient was admitted to our hospital and started on a higher dose of enoxaparin (60 mg twice daily). She was subsequently discharged home on rivaroxaban 15 mg twice daily and midodrine 2.5 mg twice daily in addition to the medications she was already taking. At her 6-week follow-up visit, she reported no recurrences.
THE TAKEAWAY
This case demonstrates that non-massive PE can present as vasovagal syncope. Recognizing that PE could lead to reflex-mediated syncope in the absence of massive emboli, it is important to rule it out in the evaluation of patients with vasovagal syncope when risk factors for PE are present.
1. Le Gal G, Righini M, Roy PM, et al. Prediction of pulmonary embolism in the emergency department: the revised Geneva score. Ann Intern Med. 2006;144:165-171.
2. Calvo-Romero JM, Pérez-Miranda M, Bureo-Dacal P. Syncope in acute pulmonary embolism. Eur J Emerg Med. 2004;11:208-209.
3. Castelli R, Tarsia P, Tantardini C, et al. Syncope in patients with pulmonary embolism: comparison between patients with syncope as the presenting symptom of pulmonary embolism and patients with pulmonary embolism without syncope. Vasc Med. 2003;8:257-261.
4. Kasper W, Konstantinides S, Geibel A, et al. Management strategies and determinants of outcome in acute major pulmonary embolism: results of a multicenter registry. J Am Coll Cardiol. 1997;30:1165-1171.
5. Koutkia P, Wachtel TJ. Pulmonary embolism presenting as syncope: case report and review of the literature. Heart Lung. 1999;28:342-347.
6. Torbicki A, Perrier A, Konstantinides S, et al; ESC Committee for Practice Guidelines (CPG). Guidelines on the diagnosis and management of acute pulmonary embolism: the Task Force for the Diagnosis and Management of Acute Pulmonary Embolism of the European Society of Cardiology (ESC). Eur Heart J. 2008;29:2276-2315.
7. Thames MD, Alpert JS, Dalen JE. Syncope in patients with pulmonary embolism. JAMA. 1977;238:2509-2511.
8. Duplyakov D, Kurakina E, Pavlova T, et al. Value of syncope in patients with high-to-intermediate risk pulmonary artery embolism. Eur Heart J Acute Cardiovasc Care. 2015;4:353-358.
9. Wilner C, Garnier-Crussard JP, Huygue De Mahenge A, et al. [Paroxysmal atrioventricular block, cause of syncope in pulmonary embolism. 2 cases]. Presse Med. 1983;12:2987-2989.
10. Frink RJ, James TN. Intracardiac route of the Bezold-Jarisch reflex. Am J Physiol. 1971;221:1464-1469.
11. Rathbun SW, Raskob GE, Whitsett TL. Sensitivity and specificity of helical computed tomography in the diagnosis of pulmonary embolism: A systematic review. Ann Intern Med. 2000;132:227-232.
12. Stein PD, Fowler SE, Goodman LR, et al; PIOPED II Investigators. Multidetector computed tomography for acute pulmonary embolism. N Engl J Med. 2006;354:2317-2327.
13. Vedovati MC, Becattini C, Agnelli G, et al. Multidetector CT scan for acute pulmonary embolism: embolic burden and clinical outcome. Chest. 2012;142:1417-1424.
14. Musset D, Parent F, Meyer G, et al; Evaluation du Scanner Spiralé dans l’Embolie Pulmonaire study group. Diagnostic strategy for patients with suspected pulmonary embolism: a prospective multicentre outcome study. Lancet. 2002;360:1914-1920.
15. Simpson RJ Jr, Podolak R, Mangano CA Jr, et al. Vagal syncope during recurrent pulmonary embolism. JAMA. 1983;249:390-393.
16. Perrier A, Roy PM, Sanchez O, et al. Multidetector-row computed tomography in suspected pulmonary embolism. N Engl J Med. 2005;352:1760-1768.
17. Le Gal G, Righini M, Parent F, et al. Diagnosis and management of subsegmental pulmonary embolism. J Thromb Haemost. 2006;4:724-731.
18. Eldadah ZA, Najjar SS, Ziegelstein RC. A patient with syncope, only “vagally” related to the heart. Chest. 2000;117:1801-1803.
1. Le Gal G, Righini M, Roy PM, et al. Prediction of pulmonary embolism in the emergency department: the revised Geneva score. Ann Intern Med. 2006;144:165-171.
2. Calvo-Romero JM, Pérez-Miranda M, Bureo-Dacal P. Syncope in acute pulmonary embolism. Eur J Emerg Med. 2004;11:208-209.
3. Castelli R, Tarsia P, Tantardini C, et al. Syncope in patients with pulmonary embolism: comparison between patients with syncope as the presenting symptom of pulmonary embolism and patients with pulmonary embolism without syncope. Vasc Med. 2003;8:257-261.
4. Kasper W, Konstantinides S, Geibel A, et al. Management strategies and determinants of outcome in acute major pulmonary embolism: results of a multicenter registry. J Am Coll Cardiol. 1997;30:1165-1171.
5. Koutkia P, Wachtel TJ. Pulmonary embolism presenting as syncope: case report and review of the literature. Heart Lung. 1999;28:342-347.
6. Torbicki A, Perrier A, Konstantinides S, et al; ESC Committee for Practice Guidelines (CPG). Guidelines on the diagnosis and management of acute pulmonary embolism: the Task Force for the Diagnosis and Management of Acute Pulmonary Embolism of the European Society of Cardiology (ESC). Eur Heart J. 2008;29:2276-2315.
7. Thames MD, Alpert JS, Dalen JE. Syncope in patients with pulmonary embolism. JAMA. 1977;238:2509-2511.
8. Duplyakov D, Kurakina E, Pavlova T, et al. Value of syncope in patients with high-to-intermediate risk pulmonary artery embolism. Eur Heart J Acute Cardiovasc Care. 2015;4:353-358.
9. Wilner C, Garnier-Crussard JP, Huygue De Mahenge A, et al. [Paroxysmal atrioventricular block, cause of syncope in pulmonary embolism. 2 cases]. Presse Med. 1983;12:2987-2989.
10. Frink RJ, James TN. Intracardiac route of the Bezold-Jarisch reflex. Am J Physiol. 1971;221:1464-1469.
11. Rathbun SW, Raskob GE, Whitsett TL. Sensitivity and specificity of helical computed tomography in the diagnosis of pulmonary embolism: A systematic review. Ann Intern Med. 2000;132:227-232.
12. Stein PD, Fowler SE, Goodman LR, et al; PIOPED II Investigators. Multidetector computed tomography for acute pulmonary embolism. N Engl J Med. 2006;354:2317-2327.
13. Vedovati MC, Becattini C, Agnelli G, et al. Multidetector CT scan for acute pulmonary embolism: embolic burden and clinical outcome. Chest. 2012;142:1417-1424.
14. Musset D, Parent F, Meyer G, et al; Evaluation du Scanner Spiralé dans l’Embolie Pulmonaire study group. Diagnostic strategy for patients with suspected pulmonary embolism: a prospective multicentre outcome study. Lancet. 2002;360:1914-1920.
15. Simpson RJ Jr, Podolak R, Mangano CA Jr, et al. Vagal syncope during recurrent pulmonary embolism. JAMA. 1983;249:390-393.
16. Perrier A, Roy PM, Sanchez O, et al. Multidetector-row computed tomography in suspected pulmonary embolism. N Engl J Med. 2005;352:1760-1768.
17. Le Gal G, Righini M, Parent F, et al. Diagnosis and management of subsegmental pulmonary embolism. J Thromb Haemost. 2006;4:724-731.
18. Eldadah ZA, Najjar SS, Ziegelstein RC. A patient with syncope, only “vagally” related to the heart. Chest. 2000;117:1801-1803.
Diabetes update: Your guide to the latest ADA standards
Prevention of diabetes, as well as early detection and treatment of both prediabetes and diabetes, is critical to the health of our country. Because evidence-based guidelines are key to our ability to effectively address the nation’s diabetes epidemic, the American Diabetes Association (ADA) updates its “Standards of Medical Care in Diabetes” annually to incorporate new evidence or clarifications.
The 2016 standards,1 available at professional.diabetes.org/jfp, are a valuable resource. Among the latest revisions: an expansion in screening recommendations, a change in the age at which aspirin therapy for women should be considered, and a change in A1C goals for pregnant women with diabetes.
As members of the ADA’s primary care advisory group, we use a question and answer format in the summary that follows to highlight recent revisions and review other recommendations that are of particular relevance to physicians in primary care. It is important to note, however, that ADA recommendations are not intended to preclude clinical judgment and should be applied in the context of excellent medical care.
Diagnosis and screening
Have the 2016 ADA standards changed the way diabetes is diagnosed?
No. The criteria for a diagnosis of diabetes did not change. Diabetes and prediabetes are still screened for and diagnosed with any of the following: a fasting plasma glucose (FPG); a 2-hour 75-g oral glucose tolerance test (OGTT); a random plasma glucose >200 mg/dL with symptoms of hyperglycemia; or A1C criteria (TABLE 1).1,2 The wording was changed, however, to make it clear that no one test is preferred over another for diagnosis.
Yes. In addition to screening asymptomatic adults of any age who are overweight or obese and have one or more additional risk factors for diabetes, the 2016 standards recommend screening all adults 45 years and older, regardless of weight.
Is an A1C <7% the recommended treatment goal for everyone with diabetes?
No. An A1C <7% is considered reasonable for most, but not all, nonpregnant adults. In the last few years, the ADA has focused more on individualized targets.
Tighter control (<6.5%)—which is associated with lower rates of eye disease, kidney disease, and nerve damage—may be appropriate for patients who have no significant hypoglycemia, no cardiovascular disease (CVD), a shorter duration of diabetes, or a longer expected lifespan.
Conversely, a higher target (<8%) may be appropriate for patients who are older, have longstanding diabetes, advanced macrovascular or microvascular disease, established complications, or a limited life expectancy.3,4
Pregnancy. The 2016 standards have a new target for pregnant women with diabetes: The ADA previously recommended an A1C <6% for this patient population, but now recommends a target A1C between 6% and 6.5%. This may be tightened or relaxed, however, depending on individual risk of hypoglycemia.
In focusing on individualized targets and hypoglycemia avoidance, the ADA notes that attention must be paid to fasting, pre-meal, and post-meal blood glucose levels to achieve treatment goals. The 2016 standards emphasize the importance of patient-centered diabetes care, aligned with a coordinated, team-based chronic care model.
Diabetes self-management education and support is indicated for those who are newly diagnosed, and should be provided periodically based on glucose control and progression of the disease. All patients should receive education on hypoglycemia risk and treatment.
Prediabetes and prevention
What is prediabetes and what can I do to prevent patients with prediabetes from developing diabetes?
Patients with impaired glucose tolerance, impaired fasting glucose, or an A1C between 5.7% and 6.4% are considered to have prediabetes and are at risk for developing type 2 diabetes.
Family physicians should refer patients with prediabetes to intensive diet, physical activity, and behavioral counseling programs like those based on the Diabetes Prevention Program study (www.niddk.nih.gov/about-niddk/research-areas/diabetes/diabetes-prevention-program-dpp/Pages/default.aspx). Goals should include a minimum 7% weight loss and moderate-intensity physical activity, such as brisk walking, for at least 150 minutes per week.
Lifestyle modification programs have been shown to be very effective in preventing diabetes, with about a 58% reduction in the risk of developing type 2 diabetes after 3 years.5 The 2016 standards added a recommendation that physicians encourage the use of new technology, such as text messaging or smart phone apps, to support such efforts.
Should I consider initiating oral antiglycemics in patients with prediabetes?
Yes. Pharmacologic agents, including metformin, acarbose, and pioglitazone, have been shown to decrease progression from prediabetes to type 2 diabetes. Thus, antiglycemics should be considered for certain patients. Metformin is especially appropriate for women with a history of gestational diabetes, patients who are younger than 60 years, and those who have a body mass index (BMI) ≥35 kg/m2.6
How often should I screen patients with prediabetes?
Patients with prediabetes should be screened annually. Such individuals should also be screened and treated for modifiable cardiovascular risk factors. There is strong evidence that the treatment of obesity can be beneficial for those at any stage of the diabetes spectrum.
Obesity management
What do the 2016 ADA standards recommend for obese patients with diabetes?
With more than two-thirds of Americans either overweight or obese, the ADA added a new section on obesity management and calls on health care providers to:
- weigh patients and calculate and document their BMI at every visit, and
- counsel those who are overweight or obese on the benefits of even modest weight loss.
The ADA recommends a sustained weight loss of 5%, which can improve glycemic control and reduce the need for diabetes medications,7-9 although weight loss of ≥7% is optimal. Physicians are also called on to assess each patient’s readiness to engage in therapeutic lifestyle change to maintain a modest weight loss.
Treatment for obesity can include therapeutic lifestyle change (reduction in calories, increase in physical activity) and behavioral therapy. For refractory patients, pharmacologic therapy and bariatric surgery may be considered.
Interventions should be high-intensity (≥16 sessions in 6 months) and focus on diet, physical activity, and behavioral strategies to achieve a 500 to 750 calorie deficit per day.10 Long-term (≥1 year) comprehensive weight maintenance programs should be prescribed for those who achieve short-term weight loss.11,12 Such programs should provide at least monthly contact and encourage ongoing monitoring of body weight (weekly or more frequently), continued consumption of a reduced-calorie diet, and participation in high levels of physical activity (200 to 300 minutes per week).
Glycemic treatment
What are some of the key factors that distinguish the different type 2 diabetes medications from one another?
An increasing understanding of diabetes pathophysiology has led to a wider array of medications, making treatment more complex than ever. It is important for physicians to have a strong working knowledge of the various classes of antidiabetic agents and the subtleties between drugs in the same class to best individualize treatment.
Here are the highlights of each class of medication listed in the ADA/European Association for the Study of Diabetes algorithm for the management of type 2 diabetes,13 which is available at http://care.diabetesjournals.org/content/38/1/140/F2.large.jpg):
Metformin is the preferred initial medication for all patients who can tolerate it and have no contraindications. The drug is cost-effective, weight neutral, and has had positive cardiovascular and mortality outcomes in long-term studies. Adverse gastrointestinal (GI) effects, including nausea, diarrhea, and dyspepsia, are common but can be reduced with a slow titration of the drug. Metformin should be used with caution in those with renal disease. The dose should be reduced if the estimated glomerular filtration rate (eGFR) <45 mL/min/1.73m2 and the drug discontinued if eGFR <30 mL/min/1.73 m2.
Sulfonylureas/meglitinides stimulate insulin secretion in a glucose-independent manner. They are cost-effective and have high efficacy early in the disease and with initial use, but the effect wanes as the disease progresses. This class of drugs is associated with weight gain and hypoglycemia. Second-generation sulfonylureas (glipizide, glimepiride) are recommended; meglitinides are more expensive than sulfonylureas.
Thiazolidinediones work to improve insulin sensitivity in the periphery and have a low risk of hypoglycemia. They have been associated with fluid retention, weight gain, and worsening of pre-existing congestive heart failure, but previous cardiovascular concerns (with rosiglitazone)14 and bladder cancer risks (with pioglitazone)15-17 have been refuted. Thiazolidinediones are contraindicated in those with Class III and IV congestive heart failure, however, and patients taking them require careful monitoring for weight gain, fluid retention, and exacerbation of heart failure.
Dipeptidyl peptidase-4 inhibitors (DPP4Is) work to reduce the breakdown of endogenous incretin hormones. These oral agents increase insulin secretion in a glucose-dependent manner; more insulin is secreted when glucose is higher and less when glucose is closer to normal. This means that there is a much lower risk of hypoglycemia when a DPP4I is used as monotherapy.
Glucagon-like peptide 1 receptor agonists (GLP-1RAs), which are injectable, also work via incretin hormones and stimulate insulin in a glucose-dependent manner. They are associated with weight loss and low rates of hypoglycemia. Adverse GI effects are common with this class of drugs, but can be reduced by titrating the medication and avoiding overeating. GLP-1RAs can be taken twice daily to once weekly, depending on the specific agent.
Sodium glucose transporter 2 inhibitors (SGLT2Is) are oral agents and the newest class of antidiabetes drugs. The drugs help block the reabsorption of glucose, thereby lowering glucose levels, blood pressure, and weight in many patients. The most common adverse effects are urinary tract and genital yeast infections. SGLT2Is should not be given to patients with advanced renal disease (chronic kidney disease Stages 3B-5) because they will not be effectively absorbed.
The US Food and Drug Administration (FDA) recently issued a warning about the risk of ketoacidosis with these agents,18 and patients should be advised to stop taking them and to seek immediate medical attention if they develop symptoms of ketoacidosis, such as excessive thirst, frequent urination, nausea and vomiting, abdominal pain, weakness or fatigue, shortness of breath, fruity-scented breath, or confusion.
Insulin is eventually needed by most patients with type 2 diabetes who live long enough to see the disease progress. The most common adverse effects are weight gain and hypoglycemia. There are many types of insulin, but only one that is delivered via inhalation—human insulin inhaled powder. Inhaled insulin, however, has the potential for adverse pulmonary effects, including cough and reduction of peak expiratory flow. Therefore, pulmonary function testing is recommended prior to its use.
Treatment goal attainment should be evaluated every 3 months, and treatment titrated at 3-month intervals if goals are not achieved. The ADA/European Association for the Study of Diabetes’ algorithm indicates that patients are likely to need insulin a year after diagnosis if their A1C goal has not been achieved or maintained.13
The following medications are not included in the algorithm but are included in the 2016 standards, and may be helpful for certain patients:
Alpha-glucosidase inhibitors delay the absorption of glucose from the proximal to distal GI tract, thereby reducing postprandial hyperglycemia. Flatulence and leakage of stool—the most common adverse effects—have limited their use in the United States.
Bile acid sequestrants (colesevelam) treat both hyperlipidemia and diabetes. The medications work by reducing glucose absorption from the GI tract. They reduce postprandial hyperglycemia, with a low risk of hypoglycemia. Colesevelam’s use is limited, however, because of the number of pills needed (6 daily).
Bromocriptine affects satiety levels via the central nervous system, and is available in a specific formulation for the treatment of diabetes. “First-dose” hypotension, however, is an adverse effect of considerable concern.1
Pramlintide, an injectable amylin mimetic given to patients on prandial insulin, can reduce postprandial glucose levels. The most common adverse effects are upper GI symptoms and hypoglycemia. Due to the adverse effects and the need for an injection with each meal, pramlintide is used infrequently.
Cardiovascular risk reduction
Has the ADA revised its recommendations for cardiovascular disease risk management?
Yes. There have been several changes. The first is in terminology, with atherosclerotic cardiovascular disease (ASCVD) replacing CVD alone. While new recommendations for statin therapy for adults older than 40 years (TABLE 2)1 were also added, the emphasis remains on therapeutic lifestyle change as an effective treatment for hypertension. These modifications should include at least 150 minutes of moderate physical activity per week and, for most patients, a reduction in total calories, saturated fat, and sodium.
It is important to remind patients that to maximize the benefits in terms of treating hyperglycemia, hypertension, and dyslipidemia, such changes must be maintained over the long term.
Aspirin therapy. The ADA also revised its recommendation regarding aspirin therapy. Based on new evidence in the treatment of women with ASCVD risk, the standards now call for considering aspirin therapy (75-162 mg/d) in both women and men ≥50 years as a primary prevention strategy for those with type 1 or type 2 diabetes with a 10-year ASCVD risk of >10%. (The previous standards recommended this only for women older than 60 years.)
Antiplatelet therapy is now recommended for patients younger than 50 years with multiple risk factors, and as secondary prevention in those with a history of ASCVD.19-21
Hypertension. The ADA’s recommendations for treating hypertension in patients with diabetes have not changed; the goal remains <140/<90 mm Hg. Lower targets may be appropriate for younger patients, those with albuminuria, and individuals with additional CVD risk factors; however, systolic pressure <130 mm Hg has not been shown to reduce CVD outcomes, and diastolic pressure <70 mm Hg has been associated with higher mortality.22
Optimal medication and lifestyle therapy are important to achieve goals, with avoidance of undue treatment burden. Angiotensin converting enzyme (ACE) inhibitors or angiotensin receptor blockers (ARBs), but not both, should be included as part of treatment. Other agents, such as a thiazide diuretic, may be needed to achieve individual goals. Serum creatinine/eGFR and serum potassium levels should be monitored with the use of diuretics.
Lipids. The 2016 standards include notable changes in lipid management. The ADA sees a role for ezetimibe for select patients, based on studies such as the IMPROVE IT trial23 that included participants with diabetes. The ADA also added a table highlighting statin recommendations and delineating high and moderate-intensity statins (TABLE 3).1 Those younger than 40 years with no other risk factors may not need a statin, but patients ages 40 or older will need moderate- to high-intensity statin therapy to effectively lower ASCVD risk.24-28
These recommendations reflect a comprehensive plan to reduce ASCVD in this at-risk population, which should also include lifestyle modification, including smoking prevention and quit strategies, as needed.
Microvascular complications
DIABETIC KIDNEY DISEASE
How should I diagnose nephropathy?
The ADA changed the terminology, referring to “diabetic kidney disease” (DKD) rather than nephropathy to highlight the fact that the focus is on kidney disease directly linked to diabetes.
Other recommendations include an annual assessment of urinary albumin (eg, spot urine albumin-to-creatinine ratio and eGFR) for patients who have had type 1 diabetes for ≥5 years and all patients who have type 2 diabetes. Two out of 3 abnormal specimens collected within a 3- to 6-month period indicate the presence of albuminuria.
What can be done to prevent or slow the progression of DKD?
Optimal BP and glycemic control are key,29-35 along with diet and medication. For patients with DKD, dietary protein intake should be 0.8 g/kg body weight per day. ACE inhibitors and ARBs have been shown to slow the decline in eGFR in patients with elevated urinary albumin excretion (≥30 mg/day).
However, neither an ACE inhibitor nor an ARB is recommended for the primary prevention of DKD in patients who have normal BP, normal urine albumin-to-creatinine ratio (<30 mg/g), and normal eGFR. In addition, combined use of an ACE inhibitor and an ARB should be avoided, as it provides no additional benefit and increases the risk of adverse effects.29
RETINOPATHY
How should I manage retinopathy in patients with diabetes?
As with the management of DKD, it is important to optimize glycemic and BP control to reduce the risk, or slow the progression, of retinopathy. Intensive diabetes management, with the goal of achieving near-normal glycemic levels, has been shown in large prospective randomized studies to prevent or delay the onset and progression of diabetic retinopathy.33,36 The presence of retinopathy is not a contraindication to aspirin therapy for ASCVD prevention, as aspirin does not increase the risk of retinal hemorrhage.
When should patients with diabetes be screened for retinopathy?
Patients with type 1 diabetes should have an initial dilated and comprehensive eye examination by an ophthalmologist or optometrist within 5 years of the onset of diabetes. Those with type 2 diabetes should have such an exam shortly after diagnosis. The exam should be repeated annually; if there is no evidence of retinopathy, however, 2-year intervals may be considered.
PERIPHERAL NEUROPATHY
When and how should I screen patients with diabetes for neuropathy?
All patients should be screened for diabetic peripheral neuropathy (DPN) starting at diagnosis of type 2 diabetes and 5 years after the diagnosis of type 1 diabetes, and continued at least annually thereafter. Assessment should include a detailed history and 10-g monofilament testing, as well as at least one of the following tests: pinprick, temperature, and vibration sensation.
It is important, too, to screen patients with more advanced diabetes for signs and symptoms of autonomic neuropathy. Signs and symptoms may include resting tachycardia, exercise intolerance, orthostatic hypotension, gastroparesis, constipation, impaired neurovascular function, and autonomic failure in response to hypoglycemia. In men, diabetic autonomic neuropathy may cause erectile dysfunction and/or retrograde ejaculation.
How should I manage patients who have DPN?
Tight glycemic control is the only measure that has been shown to prevent or delay the development of DPN or cardiac autonomic neuropathy in patients with type 1 diabetes,37,38 and to slow the progression of neuropathy in some patients with type 2 diabetes.39
The FDA has approved pregabalin, duloxetine, and tapentadol for the treatment of pain associated with DPN. Tricyclic antidepressants, gabapentin, venlafaxine, carbamazepine, tramadol, and topical capsaicin, although not approved for the treatment of painful DPN, may also be effective in treating neuropathic pain.
For those with autonomic neuropathy, dietary changes and prokinetic agents such as erythromycin may alleviate gastroparesis. Due to extrapyramidal adverse effects, metoclopramide is reserved for the most severe and unresponsive cases. Recurrent urinary tract infections, pyelonephritis, incontinence, or palpable bladder should prompt an evaluation for bladder dysfunction. Controlling lipids and BP, quitting smoking, and making other lifestyle changes can reduce both the development and the progression of autonomic neuropathy.
FOOT CARE/PERIPHERAL ARTERIAL DISEASE
What does the ADA recommend regarding foot care for patients with diabetes?
The ADA’s standards recommend an annual comprehensive foot examination to identify risk factors predictive of ulcers and potential amputations. The exam should start with inspection and assessment of foot pulses and should seek to identify loss of peripheral sensation. The examination should include inspection of the skin, assessment of foot deformities, neurologic assessment including 10-g monofilament testing and pinprick or vibration testing or assessment of ankle reflexes, and vascular assessment, including pulses in the legs and feet.40
It is also important to screen patients for peripheral arterial disease (PAD), with a comprehensive medical history and physical exam of pulses. Ankle-brachial index testing (ABI) should be performed in patients with signs or symptoms of PAD, including claudication or skin and hair changes in the lower extremities. ABI may be considered for all patients with diabetes starting at age 50 and in those younger than 50 years who have risk factors.41
Which patients with diabetes are at higher risk for foot complications?
The following are risk factors for foot complications: previous amputation, prior foot ulcer, peripheral neuropathy, foot deformity, peripheral vascular disease, visual impairment, peripheral neuropathy (especially if on dialysis), poor glycemic control, and smoking. Patients with high-risk foot conditions should be educated about their risk and appropriate management.
A well-fitted walking shoe that cushions the feet and redistributes pressure is one option to help patients. Patients with bony deformities may need extra wide or deep shoes and patients with more advanced disease may need custom-fitted shoes.
When should patients be referred to a foot specialist?
Refer patients to a foot care specialist for ongoing preventive care and lifelong surveillance if they smoke or have a history of lower-extremity complications, a loss of protective sensation, structural abnormalities, or PAD.
1. American Diabetes Association. Standards of Medical Care in Diabetes—2016. Diabetes Care. 2016;39(Suppl 1). Available at: http://care.diabetesjournals.org/site/misc/2016-Standards-of-Care.pdf. Accessed March 28, 2016.
2. International Expert Committee Report on the role of the A1C assay in the diagnosis of diabetes. Diabetes Care. 2009;32:1327-1334.
3. Lipska KJ, Ross JS, Miao Y, et al. Potential overtreatment of diabetes mellitus in older adults with tight glycemic control. JAMA Intern Med. 2015;175:356–362.
4. Vijan S, Sussman JB, Yudkin JS, et al. Effect of patients’ risks and p on health gains with plasma glucose level lowering in type 2 diabetes mellitus. JAMA Intern Med. 2014;174:1227–1234.
5. Knowler WC, Barrett-Connor E, Fowler SE, et al; Diabetes Prevention Program Research Group. Reduction in the incidence of type 2 diabetes with lifestyle intervention or metformin. N Engl J Med. 2002;346:393–403.
6. Diabetes Prevention Program Research Group. Long-term safety, tolerability, and weight loss associated with metformin in the Diabetes Prevention Program Outcomes Study. Diabetes Care. 2012;35:731–737.
7. UK Prospective Diabetes Study 7: response of fasting plasma glucose to diet therapy in newly presenting type II diabetic patients, UKPDS Group. Metabolism. 1990;39:905–912.
8. Goldstein DJ. Beneficial health effects of modest weight loss. Int J Obes Relat Metab Disord. 1992;16:397–415.
9. Pastors JG, Warshaw H, Daly A, et al. The evidence for the effectiveness of medical nutrition therapy in diabetes management. Diabetes Care. 2002;25:608–613.
10. Selph S, Dana T, Bougatsos C, et al. Screening for abnormal glucose and type 2 diabetes mellitus: a systematic review to update the 2008 US Preventive Services Task Force Recommendation. Available at: http://www.ncbi.nlm.nih.gov/books/NBK293871/. Accessed March 28, 2016.
11. Tsai AG, Wadden TA. The evolution of very-low-calorie diets: an update and metaanalysis. Obesity (Silver Spring). 2006;14:1283–1293.
12. Johansson K, Neovius M, Hemmingsson E. Effects of anti-obesity drugs, diet, and exercise on weight-loss maintenance after a very low-calorie diet or low-calorie diet: a systematic review and meta-analysis of randomized controlled trials. Am J Clin Nutr. 2014;99:14–23.
13. Inzucchi SE, Bergenstal RM, Buse JB, et al. Management of hyperglycemia in type 2 diabetes, 2015: a patient-centered approach. Update to a position statement of the American Diabetes Association and the European Association for the Study of Diabetes. Diabetes Care. 2015;38:140–149.
14. Singh S, Loke YK, Furberg CD. Long-term risk of cardiovascular events with rosiglitazone: a meta-analysis. JAMA. 2007;298:1189–1195.
15. Balaji V, Seshiah V, Ashtalakshmi G, et al. Retrospective study on finding correlation of pioglitazone and incidences of bladder cancer in the Indian population. Indian J Endocrinol Metab. 2014;18:425–427.
16. Kuo HW, Tiao MM, Ho SC, et al. Pioglitazone use and the risk of bladder cancer. Kaohsiung J Med Sci. 2014;30:94–97.
17. Wei L, MacDonald TM, Mackenzie IS. Pioglitazone and bladder cancer: a propensity score matched cohort study. Br J Clin Pharmacol. 2013;75:254-259.
18. US Food and Drug Administration. FDA Drug Safety Communication: FDA revises labels of SGLT2 inhibitors for diabetes to include warnings about too much acid in the blood and serious urinary tract infections. 2015. Available at: http://www.fda.gov/Drugs/DrugSafety/ucm475463.htm. Accessed December 11, 2015.
19. Huxley RR, Peters SAE, Mishra GD, et al. Risk of all-cause mortality and vascular events in women versus men with type 1 diabetes: a systematic review and meta-analysis. Lancet Diabetes Endocrinol. 2015;3:198–206.
20. Peters SA, Huxley RR, Woodward M. Diabetes as risk factor for incident coronary heart disease in women compared with men: a systematic review and meta-analysis of 64 cohorts including 858,507 individuals and 28,203 coronary events. Diabetologia. 2014;57:1542–1551.
21. Peters SA, Huxley RR, Woodward M. Diabetes as a risk factor for stroke in women compared with men: a systematic review and meta-analysis of 64 cohorts, including 775,385 individuals and 12,539 strokes. Lancet. 2014;383:1973-1980.
22. Cushman WC, Evans GW, Byington RP, et al; ACCORD Study Group. Effects of intensive blood-pressure control in type 2 diabetes mellitus. N Engl J Med. 2010;362:1575–1585.
23. Cannon CP, Blazing MA, Giugliano RP, et al; IMPROVE-IT Investigators. Ezetimibe added to statin therapy after acute coronary syndromes. N Engl J Med. 2015;372:2387–2397.
24. Knopp RH, d’Emden M, Smilde JG, et al. Efficacy and safety of atorvastatin in the prevention of cardiovascular end points in subjects with type 2 diabetes: the Atorvastatin Study for Prevention of Coronary Heart Disease Endpoints in non-insulin-dependent diabetes mellitus (ASPEN). Diabetes Care. 2006;29:1478–1485.
25. Colhoun HM, Betteridge DJ, Durrington PN, et al; CARDS Investigators. Primary prevention of cardiovascular disease with atorvastatin in type 2 diabetes in the Collaborative Atorvastatin Diabetes Study (CARDS): multicentre randomised placebo-controlled trial. Lancet. 2004;364:685–696.
26. Cannon CP, Braunwald E, McCabe CH, et al; Pravastatin or Atorvastatin Evaluation and Infection Therapy-Thrombolysis in Myocardial Infarction 22 Investigators. Intensive versus moderate lipid lowering with statins after acute coronary syndromes. N Engl J Med. 2004;350:1495–1504.
27. de Lemos JA, Blazing MA, Wiviott SD, et al. Early intensive vs a delayed conservative simvastatin strategy in patients with acute coronary syndromes: phase Z of the A to Z trial. JAMA. 2004;292:1307–1316.
28. Nissen SE, Tuzcu EM, Schoenhagen P, et al; REVERSAL Investigators. Effect of intensive compared with moderate lipid-lowering therapy on progression of coronary atherosclerosis: a randomized controlled trial. JAMA. 2004;291:1071–1080.
29. UK Prospective Diabetes Study Group. Tight blood pressure control and risk of macrovascular and microvascular complications in type 2 diabetes: UKPDS 38. BMJ. 1998;317:703–713.
30. Tuttle KR, Bakris GL, Bilous RW, et al. Diabetic kidney disease: a report from an American Diabetes Association Consensus Conference. Diabetes Care. 2014;37:2864–2883.
31. The Diabetes Control and Complications (DCCT) Research Group. Effect of intensive therapy on the development and progression of diabetic nephropathy in the Diabetes Control and Complications Trial. Kidney Int. 1995;47:1703–1720.
32. UK Prospective Diabetes Study (UKPDS) Group. Effect of intensive blood-glucose control with metformin on complications in overweight patients with type 2 diabetes (UKPDS 34). Lancet. 1998;352:854–865.
33. UK Prospective Diabetes Study (UKPDS) Group. Intensive blood-glucose control with sulphonylureas or insulin compared with conventional treatment and risk of complications in patients with type 2 diabetes (UKPDS 33). Lancet. 1998;352:837–853.
34. Patel A, MacMahon S, Chalmers J, et al; ADVANCE Collaborative Group. Intensive blood glucose control and vascular outcomes in patients with type 2 diabetes. N Engl J Med. 2008;358:2560–2572.
35. Ismail-Beigi F, Craven T, Banerji MA, et al; ACCORD Trial Group. Effect of intensive treatment of hyperglycaemia on microvascular outcomes in type 2 diabetes: an analysis of the ACCORD randomised trial. Lancet. 2010;376:419–430.
36. Yusuf S, Teo KK, Pogue J, et al; ONTARGET Investigators. Telmisartan, ramipril, or both in patients at high risk for vascular events. N Engl J Med. 2008;358:1547–1559.
37. Chew EY, Ambrosius WT, Davis MD, et al; ACCORD Study Group; ACCORD Eye Study Group. Effects of medical therapies on retinopathy progression in type 2 diabetes. N Engl J Med. 2010;363:233–244.
38. Ang L, Jaiswal M, Martin C, et al. Glucose control and diabetic neuropathy: lessons from recent large clinical trials. Curr Diab Rep. 2014;14:528.
39. Martin CL, Albers JW, Pop-Busui R; DCCT/EDIC Research Group. Neuropathy and related findings in the Diabetes Control and Complications Trial/Epidemiology of Diabetes Interventions and Complications study. Diabetes Care. 2014;37:31–38.
40. Bril V, England J, Franklin GM, et al; American Academy of Neurology; American Association of Neuromuscular and Electrodiagnostic Medicine; American Academy of Physical Medicine and Rehabilitation. Evidence-based guideline: treatment of painful diabetic neuropathy: report of the American Academy of Neurology, the American Association of Neuromuscular and Electrodiagnostic Medicine, and the American Academy of Physical Medicine and Rehabilitation. Neurology. 2011;76:1758–1765.
41. American Diabetes Association. Peripheral arterial disease in people with diabetes. Diabetes Care. 2003;26:3333–3341.
42. Centers for Disease Control and Prevention. Recommended adult immunization schedule for adults aged 19 years or older, by vaccine and age group. United States, 2016. Available at: http://www.cdc.gov/vaccines/schedules/hcp/imz/adult.html. Accessed April 8, 2016.
Prevention of diabetes, as well as early detection and treatment of both prediabetes and diabetes, is critical to the health of our country. Because evidence-based guidelines are key to our ability to effectively address the nation’s diabetes epidemic, the American Diabetes Association (ADA) updates its “Standards of Medical Care in Diabetes” annually to incorporate new evidence or clarifications.
The 2016 standards,1 available at professional.diabetes.org/jfp, are a valuable resource. Among the latest revisions: an expansion in screening recommendations, a change in the age at which aspirin therapy for women should be considered, and a change in A1C goals for pregnant women with diabetes.
As members of the ADA’s primary care advisory group, we use a question and answer format in the summary that follows to highlight recent revisions and review other recommendations that are of particular relevance to physicians in primary care. It is important to note, however, that ADA recommendations are not intended to preclude clinical judgment and should be applied in the context of excellent medical care.
Diagnosis and screening
Have the 2016 ADA standards changed the way diabetes is diagnosed?
No. The criteria for a diagnosis of diabetes did not change. Diabetes and prediabetes are still screened for and diagnosed with any of the following: a fasting plasma glucose (FPG); a 2-hour 75-g oral glucose tolerance test (OGTT); a random plasma glucose >200 mg/dL with symptoms of hyperglycemia; or A1C criteria (TABLE 1).1,2 The wording was changed, however, to make it clear that no one test is preferred over another for diagnosis.
Yes. In addition to screening asymptomatic adults of any age who are overweight or obese and have one or more additional risk factors for diabetes, the 2016 standards recommend screening all adults 45 years and older, regardless of weight.
Is an A1C <7% the recommended treatment goal for everyone with diabetes?
No. An A1C <7% is considered reasonable for most, but not all, nonpregnant adults. In the last few years, the ADA has focused more on individualized targets.
Tighter control (<6.5%)—which is associated with lower rates of eye disease, kidney disease, and nerve damage—may be appropriate for patients who have no significant hypoglycemia, no cardiovascular disease (CVD), a shorter duration of diabetes, or a longer expected lifespan.
Conversely, a higher target (<8%) may be appropriate for patients who are older, have longstanding diabetes, advanced macrovascular or microvascular disease, established complications, or a limited life expectancy.3,4
Pregnancy. The 2016 standards have a new target for pregnant women with diabetes: The ADA previously recommended an A1C <6% for this patient population, but now recommends a target A1C between 6% and 6.5%. This may be tightened or relaxed, however, depending on individual risk of hypoglycemia.
In focusing on individualized targets and hypoglycemia avoidance, the ADA notes that attention must be paid to fasting, pre-meal, and post-meal blood glucose levels to achieve treatment goals. The 2016 standards emphasize the importance of patient-centered diabetes care, aligned with a coordinated, team-based chronic care model.
Diabetes self-management education and support is indicated for those who are newly diagnosed, and should be provided periodically based on glucose control and progression of the disease. All patients should receive education on hypoglycemia risk and treatment.
Prediabetes and prevention
What is prediabetes and what can I do to prevent patients with prediabetes from developing diabetes?
Patients with impaired glucose tolerance, impaired fasting glucose, or an A1C between 5.7% and 6.4% are considered to have prediabetes and are at risk for developing type 2 diabetes.
Family physicians should refer patients with prediabetes to intensive diet, physical activity, and behavioral counseling programs like those based on the Diabetes Prevention Program study (www.niddk.nih.gov/about-niddk/research-areas/diabetes/diabetes-prevention-program-dpp/Pages/default.aspx). Goals should include a minimum 7% weight loss and moderate-intensity physical activity, such as brisk walking, for at least 150 minutes per week.
Lifestyle modification programs have been shown to be very effective in preventing diabetes, with about a 58% reduction in the risk of developing type 2 diabetes after 3 years.5 The 2016 standards added a recommendation that physicians encourage the use of new technology, such as text messaging or smart phone apps, to support such efforts.
Should I consider initiating oral antiglycemics in patients with prediabetes?
Yes. Pharmacologic agents, including metformin, acarbose, and pioglitazone, have been shown to decrease progression from prediabetes to type 2 diabetes. Thus, antiglycemics should be considered for certain patients. Metformin is especially appropriate for women with a history of gestational diabetes, patients who are younger than 60 years, and those who have a body mass index (BMI) ≥35 kg/m2.6
How often should I screen patients with prediabetes?
Patients with prediabetes should be screened annually. Such individuals should also be screened and treated for modifiable cardiovascular risk factors. There is strong evidence that the treatment of obesity can be beneficial for those at any stage of the diabetes spectrum.
Obesity management
What do the 2016 ADA standards recommend for obese patients with diabetes?
With more than two-thirds of Americans either overweight or obese, the ADA added a new section on obesity management and calls on health care providers to:
- weigh patients and calculate and document their BMI at every visit, and
- counsel those who are overweight or obese on the benefits of even modest weight loss.
The ADA recommends a sustained weight loss of 5%, which can improve glycemic control and reduce the need for diabetes medications,7-9 although weight loss of ≥7% is optimal. Physicians are also called on to assess each patient’s readiness to engage in therapeutic lifestyle change to maintain a modest weight loss.
Treatment for obesity can include therapeutic lifestyle change (reduction in calories, increase in physical activity) and behavioral therapy. For refractory patients, pharmacologic therapy and bariatric surgery may be considered.
Interventions should be high-intensity (≥16 sessions in 6 months) and focus on diet, physical activity, and behavioral strategies to achieve a 500 to 750 calorie deficit per day.10 Long-term (≥1 year) comprehensive weight maintenance programs should be prescribed for those who achieve short-term weight loss.11,12 Such programs should provide at least monthly contact and encourage ongoing monitoring of body weight (weekly or more frequently), continued consumption of a reduced-calorie diet, and participation in high levels of physical activity (200 to 300 minutes per week).
Glycemic treatment
What are some of the key factors that distinguish the different type 2 diabetes medications from one another?
An increasing understanding of diabetes pathophysiology has led to a wider array of medications, making treatment more complex than ever. It is important for physicians to have a strong working knowledge of the various classes of antidiabetic agents and the subtleties between drugs in the same class to best individualize treatment.
Here are the highlights of each class of medication listed in the ADA/European Association for the Study of Diabetes algorithm for the management of type 2 diabetes,13 which is available at http://care.diabetesjournals.org/content/38/1/140/F2.large.jpg):
Metformin is the preferred initial medication for all patients who can tolerate it and have no contraindications. The drug is cost-effective, weight neutral, and has had positive cardiovascular and mortality outcomes in long-term studies. Adverse gastrointestinal (GI) effects, including nausea, diarrhea, and dyspepsia, are common but can be reduced with a slow titration of the drug. Metformin should be used with caution in those with renal disease. The dose should be reduced if the estimated glomerular filtration rate (eGFR) <45 mL/min/1.73m2 and the drug discontinued if eGFR <30 mL/min/1.73 m2.
Sulfonylureas/meglitinides stimulate insulin secretion in a glucose-independent manner. They are cost-effective and have high efficacy early in the disease and with initial use, but the effect wanes as the disease progresses. This class of drugs is associated with weight gain and hypoglycemia. Second-generation sulfonylureas (glipizide, glimepiride) are recommended; meglitinides are more expensive than sulfonylureas.
Thiazolidinediones work to improve insulin sensitivity in the periphery and have a low risk of hypoglycemia. They have been associated with fluid retention, weight gain, and worsening of pre-existing congestive heart failure, but previous cardiovascular concerns (with rosiglitazone)14 and bladder cancer risks (with pioglitazone)15-17 have been refuted. Thiazolidinediones are contraindicated in those with Class III and IV congestive heart failure, however, and patients taking them require careful monitoring for weight gain, fluid retention, and exacerbation of heart failure.
Dipeptidyl peptidase-4 inhibitors (DPP4Is) work to reduce the breakdown of endogenous incretin hormones. These oral agents increase insulin secretion in a glucose-dependent manner; more insulin is secreted when glucose is higher and less when glucose is closer to normal. This means that there is a much lower risk of hypoglycemia when a DPP4I is used as monotherapy.
Glucagon-like peptide 1 receptor agonists (GLP-1RAs), which are injectable, also work via incretin hormones and stimulate insulin in a glucose-dependent manner. They are associated with weight loss and low rates of hypoglycemia. Adverse GI effects are common with this class of drugs, but can be reduced by titrating the medication and avoiding overeating. GLP-1RAs can be taken twice daily to once weekly, depending on the specific agent.
Sodium glucose transporter 2 inhibitors (SGLT2Is) are oral agents and the newest class of antidiabetes drugs. The drugs help block the reabsorption of glucose, thereby lowering glucose levels, blood pressure, and weight in many patients. The most common adverse effects are urinary tract and genital yeast infections. SGLT2Is should not be given to patients with advanced renal disease (chronic kidney disease Stages 3B-5) because they will not be effectively absorbed.
The US Food and Drug Administration (FDA) recently issued a warning about the risk of ketoacidosis with these agents,18 and patients should be advised to stop taking them and to seek immediate medical attention if they develop symptoms of ketoacidosis, such as excessive thirst, frequent urination, nausea and vomiting, abdominal pain, weakness or fatigue, shortness of breath, fruity-scented breath, or confusion.
Insulin is eventually needed by most patients with type 2 diabetes who live long enough to see the disease progress. The most common adverse effects are weight gain and hypoglycemia. There are many types of insulin, but only one that is delivered via inhalation—human insulin inhaled powder. Inhaled insulin, however, has the potential for adverse pulmonary effects, including cough and reduction of peak expiratory flow. Therefore, pulmonary function testing is recommended prior to its use.
Treatment goal attainment should be evaluated every 3 months, and treatment titrated at 3-month intervals if goals are not achieved. The ADA/European Association for the Study of Diabetes’ algorithm indicates that patients are likely to need insulin a year after diagnosis if their A1C goal has not been achieved or maintained.13
The following medications are not included in the algorithm but are included in the 2016 standards, and may be helpful for certain patients:
Alpha-glucosidase inhibitors delay the absorption of glucose from the proximal to distal GI tract, thereby reducing postprandial hyperglycemia. Flatulence and leakage of stool—the most common adverse effects—have limited their use in the United States.
Bile acid sequestrants (colesevelam) treat both hyperlipidemia and diabetes. The medications work by reducing glucose absorption from the GI tract. They reduce postprandial hyperglycemia, with a low risk of hypoglycemia. Colesevelam’s use is limited, however, because of the number of pills needed (6 daily).
Bromocriptine affects satiety levels via the central nervous system, and is available in a specific formulation for the treatment of diabetes. “First-dose” hypotension, however, is an adverse effect of considerable concern.1
Pramlintide, an injectable amylin mimetic given to patients on prandial insulin, can reduce postprandial glucose levels. The most common adverse effects are upper GI symptoms and hypoglycemia. Due to the adverse effects and the need for an injection with each meal, pramlintide is used infrequently.
Cardiovascular risk reduction
Has the ADA revised its recommendations for cardiovascular disease risk management?
Yes. There have been several changes. The first is in terminology, with atherosclerotic cardiovascular disease (ASCVD) replacing CVD alone. While new recommendations for statin therapy for adults older than 40 years (TABLE 2)1 were also added, the emphasis remains on therapeutic lifestyle change as an effective treatment for hypertension. These modifications should include at least 150 minutes of moderate physical activity per week and, for most patients, a reduction in total calories, saturated fat, and sodium.
It is important to remind patients that to maximize the benefits in terms of treating hyperglycemia, hypertension, and dyslipidemia, such changes must be maintained over the long term.
Aspirin therapy. The ADA also revised its recommendation regarding aspirin therapy. Based on new evidence in the treatment of women with ASCVD risk, the standards now call for considering aspirin therapy (75-162 mg/d) in both women and men ≥50 years as a primary prevention strategy for those with type 1 or type 2 diabetes with a 10-year ASCVD risk of >10%. (The previous standards recommended this only for women older than 60 years.)
Antiplatelet therapy is now recommended for patients younger than 50 years with multiple risk factors, and as secondary prevention in those with a history of ASCVD.19-21
Hypertension. The ADA’s recommendations for treating hypertension in patients with diabetes have not changed; the goal remains <140/<90 mm Hg. Lower targets may be appropriate for younger patients, those with albuminuria, and individuals with additional CVD risk factors; however, systolic pressure <130 mm Hg has not been shown to reduce CVD outcomes, and diastolic pressure <70 mm Hg has been associated with higher mortality.22
Optimal medication and lifestyle therapy are important to achieve goals, with avoidance of undue treatment burden. Angiotensin converting enzyme (ACE) inhibitors or angiotensin receptor blockers (ARBs), but not both, should be included as part of treatment. Other agents, such as a thiazide diuretic, may be needed to achieve individual goals. Serum creatinine/eGFR and serum potassium levels should be monitored with the use of diuretics.
Lipids. The 2016 standards include notable changes in lipid management. The ADA sees a role for ezetimibe for select patients, based on studies such as the IMPROVE IT trial23 that included participants with diabetes. The ADA also added a table highlighting statin recommendations and delineating high and moderate-intensity statins (TABLE 3).1 Those younger than 40 years with no other risk factors may not need a statin, but patients ages 40 or older will need moderate- to high-intensity statin therapy to effectively lower ASCVD risk.24-28
These recommendations reflect a comprehensive plan to reduce ASCVD in this at-risk population, which should also include lifestyle modification, including smoking prevention and quit strategies, as needed.
Microvascular complications
DIABETIC KIDNEY DISEASE
How should I diagnose nephropathy?
The ADA changed the terminology, referring to “diabetic kidney disease” (DKD) rather than nephropathy to highlight the fact that the focus is on kidney disease directly linked to diabetes.
Other recommendations include an annual assessment of urinary albumin (eg, spot urine albumin-to-creatinine ratio and eGFR) for patients who have had type 1 diabetes for ≥5 years and all patients who have type 2 diabetes. Two out of 3 abnormal specimens collected within a 3- to 6-month period indicate the presence of albuminuria.
What can be done to prevent or slow the progression of DKD?
Optimal BP and glycemic control are key,29-35 along with diet and medication. For patients with DKD, dietary protein intake should be 0.8 g/kg body weight per day. ACE inhibitors and ARBs have been shown to slow the decline in eGFR in patients with elevated urinary albumin excretion (≥30 mg/day).
However, neither an ACE inhibitor nor an ARB is recommended for the primary prevention of DKD in patients who have normal BP, normal urine albumin-to-creatinine ratio (<30 mg/g), and normal eGFR. In addition, combined use of an ACE inhibitor and an ARB should be avoided, as it provides no additional benefit and increases the risk of adverse effects.29
RETINOPATHY
How should I manage retinopathy in patients with diabetes?
As with the management of DKD, it is important to optimize glycemic and BP control to reduce the risk, or slow the progression, of retinopathy. Intensive diabetes management, with the goal of achieving near-normal glycemic levels, has been shown in large prospective randomized studies to prevent or delay the onset and progression of diabetic retinopathy.33,36 The presence of retinopathy is not a contraindication to aspirin therapy for ASCVD prevention, as aspirin does not increase the risk of retinal hemorrhage.
When should patients with diabetes be screened for retinopathy?
Patients with type 1 diabetes should have an initial dilated and comprehensive eye examination by an ophthalmologist or optometrist within 5 years of the onset of diabetes. Those with type 2 diabetes should have such an exam shortly after diagnosis. The exam should be repeated annually; if there is no evidence of retinopathy, however, 2-year intervals may be considered.
PERIPHERAL NEUROPATHY
When and how should I screen patients with diabetes for neuropathy?
All patients should be screened for diabetic peripheral neuropathy (DPN) starting at diagnosis of type 2 diabetes and 5 years after the diagnosis of type 1 diabetes, and continued at least annually thereafter. Assessment should include a detailed history and 10-g monofilament testing, as well as at least one of the following tests: pinprick, temperature, and vibration sensation.
It is important, too, to screen patients with more advanced diabetes for signs and symptoms of autonomic neuropathy. Signs and symptoms may include resting tachycardia, exercise intolerance, orthostatic hypotension, gastroparesis, constipation, impaired neurovascular function, and autonomic failure in response to hypoglycemia. In men, diabetic autonomic neuropathy may cause erectile dysfunction and/or retrograde ejaculation.
How should I manage patients who have DPN?
Tight glycemic control is the only measure that has been shown to prevent or delay the development of DPN or cardiac autonomic neuropathy in patients with type 1 diabetes,37,38 and to slow the progression of neuropathy in some patients with type 2 diabetes.39
The FDA has approved pregabalin, duloxetine, and tapentadol for the treatment of pain associated with DPN. Tricyclic antidepressants, gabapentin, venlafaxine, carbamazepine, tramadol, and topical capsaicin, although not approved for the treatment of painful DPN, may also be effective in treating neuropathic pain.
For those with autonomic neuropathy, dietary changes and prokinetic agents such as erythromycin may alleviate gastroparesis. Due to extrapyramidal adverse effects, metoclopramide is reserved for the most severe and unresponsive cases. Recurrent urinary tract infections, pyelonephritis, incontinence, or palpable bladder should prompt an evaluation for bladder dysfunction. Controlling lipids and BP, quitting smoking, and making other lifestyle changes can reduce both the development and the progression of autonomic neuropathy.
FOOT CARE/PERIPHERAL ARTERIAL DISEASE
What does the ADA recommend regarding foot care for patients with diabetes?
The ADA’s standards recommend an annual comprehensive foot examination to identify risk factors predictive of ulcers and potential amputations. The exam should start with inspection and assessment of foot pulses and should seek to identify loss of peripheral sensation. The examination should include inspection of the skin, assessment of foot deformities, neurologic assessment including 10-g monofilament testing and pinprick or vibration testing or assessment of ankle reflexes, and vascular assessment, including pulses in the legs and feet.40
It is also important to screen patients for peripheral arterial disease (PAD), with a comprehensive medical history and physical exam of pulses. Ankle-brachial index testing (ABI) should be performed in patients with signs or symptoms of PAD, including claudication or skin and hair changes in the lower extremities. ABI may be considered for all patients with diabetes starting at age 50 and in those younger than 50 years who have risk factors.41
Which patients with diabetes are at higher risk for foot complications?
The following are risk factors for foot complications: previous amputation, prior foot ulcer, peripheral neuropathy, foot deformity, peripheral vascular disease, visual impairment, peripheral neuropathy (especially if on dialysis), poor glycemic control, and smoking. Patients with high-risk foot conditions should be educated about their risk and appropriate management.
A well-fitted walking shoe that cushions the feet and redistributes pressure is one option to help patients. Patients with bony deformities may need extra wide or deep shoes and patients with more advanced disease may need custom-fitted shoes.
When should patients be referred to a foot specialist?
Refer patients to a foot care specialist for ongoing preventive care and lifelong surveillance if they smoke or have a history of lower-extremity complications, a loss of protective sensation, structural abnormalities, or PAD.
Prevention of diabetes, as well as early detection and treatment of both prediabetes and diabetes, is critical to the health of our country. Because evidence-based guidelines are key to our ability to effectively address the nation’s diabetes epidemic, the American Diabetes Association (ADA) updates its “Standards of Medical Care in Diabetes” annually to incorporate new evidence or clarifications.
The 2016 standards,1 available at professional.diabetes.org/jfp, are a valuable resource. Among the latest revisions: an expansion in screening recommendations, a change in the age at which aspirin therapy for women should be considered, and a change in A1C goals for pregnant women with diabetes.
As members of the ADA’s primary care advisory group, we use a question and answer format in the summary that follows to highlight recent revisions and review other recommendations that are of particular relevance to physicians in primary care. It is important to note, however, that ADA recommendations are not intended to preclude clinical judgment and should be applied in the context of excellent medical care.
Diagnosis and screening
Have the 2016 ADA standards changed the way diabetes is diagnosed?
No. The criteria for a diagnosis of diabetes did not change. Diabetes and prediabetes are still screened for and diagnosed with any of the following: a fasting plasma glucose (FPG); a 2-hour 75-g oral glucose tolerance test (OGTT); a random plasma glucose >200 mg/dL with symptoms of hyperglycemia; or A1C criteria (TABLE 1).1,2 The wording was changed, however, to make it clear that no one test is preferred over another for diagnosis.
Yes. In addition to screening asymptomatic adults of any age who are overweight or obese and have one or more additional risk factors for diabetes, the 2016 standards recommend screening all adults 45 years and older, regardless of weight.
Is an A1C <7% the recommended treatment goal for everyone with diabetes?
No. An A1C <7% is considered reasonable for most, but not all, nonpregnant adults. In the last few years, the ADA has focused more on individualized targets.
Tighter control (<6.5%)—which is associated with lower rates of eye disease, kidney disease, and nerve damage—may be appropriate for patients who have no significant hypoglycemia, no cardiovascular disease (CVD), a shorter duration of diabetes, or a longer expected lifespan.
Conversely, a higher target (<8%) may be appropriate for patients who are older, have longstanding diabetes, advanced macrovascular or microvascular disease, established complications, or a limited life expectancy.3,4
Pregnancy. The 2016 standards have a new target for pregnant women with diabetes: The ADA previously recommended an A1C <6% for this patient population, but now recommends a target A1C between 6% and 6.5%. This may be tightened or relaxed, however, depending on individual risk of hypoglycemia.
In focusing on individualized targets and hypoglycemia avoidance, the ADA notes that attention must be paid to fasting, pre-meal, and post-meal blood glucose levels to achieve treatment goals. The 2016 standards emphasize the importance of patient-centered diabetes care, aligned with a coordinated, team-based chronic care model.
Diabetes self-management education and support is indicated for those who are newly diagnosed, and should be provided periodically based on glucose control and progression of the disease. All patients should receive education on hypoglycemia risk and treatment.
Prediabetes and prevention
What is prediabetes and what can I do to prevent patients with prediabetes from developing diabetes?
Patients with impaired glucose tolerance, impaired fasting glucose, or an A1C between 5.7% and 6.4% are considered to have prediabetes and are at risk for developing type 2 diabetes.
Family physicians should refer patients with prediabetes to intensive diet, physical activity, and behavioral counseling programs like those based on the Diabetes Prevention Program study (www.niddk.nih.gov/about-niddk/research-areas/diabetes/diabetes-prevention-program-dpp/Pages/default.aspx). Goals should include a minimum 7% weight loss and moderate-intensity physical activity, such as brisk walking, for at least 150 minutes per week.
Lifestyle modification programs have been shown to be very effective in preventing diabetes, with about a 58% reduction in the risk of developing type 2 diabetes after 3 years.5 The 2016 standards added a recommendation that physicians encourage the use of new technology, such as text messaging or smart phone apps, to support such efforts.
Should I consider initiating oral antiglycemics in patients with prediabetes?
Yes. Pharmacologic agents, including metformin, acarbose, and pioglitazone, have been shown to decrease progression from prediabetes to type 2 diabetes. Thus, antiglycemics should be considered for certain patients. Metformin is especially appropriate for women with a history of gestational diabetes, patients who are younger than 60 years, and those who have a body mass index (BMI) ≥35 kg/m2.6
How often should I screen patients with prediabetes?
Patients with prediabetes should be screened annually. Such individuals should also be screened and treated for modifiable cardiovascular risk factors. There is strong evidence that the treatment of obesity can be beneficial for those at any stage of the diabetes spectrum.
Obesity management
What do the 2016 ADA standards recommend for obese patients with diabetes?
With more than two-thirds of Americans either overweight or obese, the ADA added a new section on obesity management and calls on health care providers to:
- weigh patients and calculate and document their BMI at every visit, and
- counsel those who are overweight or obese on the benefits of even modest weight loss.
The ADA recommends a sustained weight loss of 5%, which can improve glycemic control and reduce the need for diabetes medications,7-9 although weight loss of ≥7% is optimal. Physicians are also called on to assess each patient’s readiness to engage in therapeutic lifestyle change to maintain a modest weight loss.
Treatment for obesity can include therapeutic lifestyle change (reduction in calories, increase in physical activity) and behavioral therapy. For refractory patients, pharmacologic therapy and bariatric surgery may be considered.
Interventions should be high-intensity (≥16 sessions in 6 months) and focus on diet, physical activity, and behavioral strategies to achieve a 500 to 750 calorie deficit per day.10 Long-term (≥1 year) comprehensive weight maintenance programs should be prescribed for those who achieve short-term weight loss.11,12 Such programs should provide at least monthly contact and encourage ongoing monitoring of body weight (weekly or more frequently), continued consumption of a reduced-calorie diet, and participation in high levels of physical activity (200 to 300 minutes per week).
Glycemic treatment
What are some of the key factors that distinguish the different type 2 diabetes medications from one another?
An increasing understanding of diabetes pathophysiology has led to a wider array of medications, making treatment more complex than ever. It is important for physicians to have a strong working knowledge of the various classes of antidiabetic agents and the subtleties between drugs in the same class to best individualize treatment.
Here are the highlights of each class of medication listed in the ADA/European Association for the Study of Diabetes algorithm for the management of type 2 diabetes,13 which is available at http://care.diabetesjournals.org/content/38/1/140/F2.large.jpg):
Metformin is the preferred initial medication for all patients who can tolerate it and have no contraindications. The drug is cost-effective, weight neutral, and has had positive cardiovascular and mortality outcomes in long-term studies. Adverse gastrointestinal (GI) effects, including nausea, diarrhea, and dyspepsia, are common but can be reduced with a slow titration of the drug. Metformin should be used with caution in those with renal disease. The dose should be reduced if the estimated glomerular filtration rate (eGFR) <45 mL/min/1.73m2 and the drug discontinued if eGFR <30 mL/min/1.73 m2.
Sulfonylureas/meglitinides stimulate insulin secretion in a glucose-independent manner. They are cost-effective and have high efficacy early in the disease and with initial use, but the effect wanes as the disease progresses. This class of drugs is associated with weight gain and hypoglycemia. Second-generation sulfonylureas (glipizide, glimepiride) are recommended; meglitinides are more expensive than sulfonylureas.
Thiazolidinediones work to improve insulin sensitivity in the periphery and have a low risk of hypoglycemia. They have been associated with fluid retention, weight gain, and worsening of pre-existing congestive heart failure, but previous cardiovascular concerns (with rosiglitazone)14 and bladder cancer risks (with pioglitazone)15-17 have been refuted. Thiazolidinediones are contraindicated in those with Class III and IV congestive heart failure, however, and patients taking them require careful monitoring for weight gain, fluid retention, and exacerbation of heart failure.
Dipeptidyl peptidase-4 inhibitors (DPP4Is) work to reduce the breakdown of endogenous incretin hormones. These oral agents increase insulin secretion in a glucose-dependent manner; more insulin is secreted when glucose is higher and less when glucose is closer to normal. This means that there is a much lower risk of hypoglycemia when a DPP4I is used as monotherapy.
Glucagon-like peptide 1 receptor agonists (GLP-1RAs), which are injectable, also work via incretin hormones and stimulate insulin in a glucose-dependent manner. They are associated with weight loss and low rates of hypoglycemia. Adverse GI effects are common with this class of drugs, but can be reduced by titrating the medication and avoiding overeating. GLP-1RAs can be taken twice daily to once weekly, depending on the specific agent.
Sodium glucose transporter 2 inhibitors (SGLT2Is) are oral agents and the newest class of antidiabetes drugs. The drugs help block the reabsorption of glucose, thereby lowering glucose levels, blood pressure, and weight in many patients. The most common adverse effects are urinary tract and genital yeast infections. SGLT2Is should not be given to patients with advanced renal disease (chronic kidney disease Stages 3B-5) because they will not be effectively absorbed.
The US Food and Drug Administration (FDA) recently issued a warning about the risk of ketoacidosis with these agents,18 and patients should be advised to stop taking them and to seek immediate medical attention if they develop symptoms of ketoacidosis, such as excessive thirst, frequent urination, nausea and vomiting, abdominal pain, weakness or fatigue, shortness of breath, fruity-scented breath, or confusion.
Insulin is eventually needed by most patients with type 2 diabetes who live long enough to see the disease progress. The most common adverse effects are weight gain and hypoglycemia. There are many types of insulin, but only one that is delivered via inhalation—human insulin inhaled powder. Inhaled insulin, however, has the potential for adverse pulmonary effects, including cough and reduction of peak expiratory flow. Therefore, pulmonary function testing is recommended prior to its use.
Treatment goal attainment should be evaluated every 3 months, and treatment titrated at 3-month intervals if goals are not achieved. The ADA/European Association for the Study of Diabetes’ algorithm indicates that patients are likely to need insulin a year after diagnosis if their A1C goal has not been achieved or maintained.13
The following medications are not included in the algorithm but are included in the 2016 standards, and may be helpful for certain patients:
Alpha-glucosidase inhibitors delay the absorption of glucose from the proximal to distal GI tract, thereby reducing postprandial hyperglycemia. Flatulence and leakage of stool—the most common adverse effects—have limited their use in the United States.
Bile acid sequestrants (colesevelam) treat both hyperlipidemia and diabetes. The medications work by reducing glucose absorption from the GI tract. They reduce postprandial hyperglycemia, with a low risk of hypoglycemia. Colesevelam’s use is limited, however, because of the number of pills needed (6 daily).
Bromocriptine affects satiety levels via the central nervous system, and is available in a specific formulation for the treatment of diabetes. “First-dose” hypotension, however, is an adverse effect of considerable concern.1
Pramlintide, an injectable amylin mimetic given to patients on prandial insulin, can reduce postprandial glucose levels. The most common adverse effects are upper GI symptoms and hypoglycemia. Due to the adverse effects and the need for an injection with each meal, pramlintide is used infrequently.
Cardiovascular risk reduction
Has the ADA revised its recommendations for cardiovascular disease risk management?
Yes. There have been several changes. The first is in terminology, with atherosclerotic cardiovascular disease (ASCVD) replacing CVD alone. While new recommendations for statin therapy for adults older than 40 years (TABLE 2)1 were also added, the emphasis remains on therapeutic lifestyle change as an effective treatment for hypertension. These modifications should include at least 150 minutes of moderate physical activity per week and, for most patients, a reduction in total calories, saturated fat, and sodium.
It is important to remind patients that to maximize the benefits in terms of treating hyperglycemia, hypertension, and dyslipidemia, such changes must be maintained over the long term.
Aspirin therapy. The ADA also revised its recommendation regarding aspirin therapy. Based on new evidence in the treatment of women with ASCVD risk, the standards now call for considering aspirin therapy (75-162 mg/d) in both women and men ≥50 years as a primary prevention strategy for those with type 1 or type 2 diabetes with a 10-year ASCVD risk of >10%. (The previous standards recommended this only for women older than 60 years.)
Antiplatelet therapy is now recommended for patients younger than 50 years with multiple risk factors, and as secondary prevention in those with a history of ASCVD.19-21
Hypertension. The ADA’s recommendations for treating hypertension in patients with diabetes have not changed; the goal remains <140/<90 mm Hg. Lower targets may be appropriate for younger patients, those with albuminuria, and individuals with additional CVD risk factors; however, systolic pressure <130 mm Hg has not been shown to reduce CVD outcomes, and diastolic pressure <70 mm Hg has been associated with higher mortality.22
Optimal medication and lifestyle therapy are important to achieve goals, with avoidance of undue treatment burden. Angiotensin converting enzyme (ACE) inhibitors or angiotensin receptor blockers (ARBs), but not both, should be included as part of treatment. Other agents, such as a thiazide diuretic, may be needed to achieve individual goals. Serum creatinine/eGFR and serum potassium levels should be monitored with the use of diuretics.
Lipids. The 2016 standards include notable changes in lipid management. The ADA sees a role for ezetimibe for select patients, based on studies such as the IMPROVE IT trial23 that included participants with diabetes. The ADA also added a table highlighting statin recommendations and delineating high and moderate-intensity statins (TABLE 3).1 Those younger than 40 years with no other risk factors may not need a statin, but patients ages 40 or older will need moderate- to high-intensity statin therapy to effectively lower ASCVD risk.24-28
These recommendations reflect a comprehensive plan to reduce ASCVD in this at-risk population, which should also include lifestyle modification, including smoking prevention and quit strategies, as needed.
Microvascular complications
DIABETIC KIDNEY DISEASE
How should I diagnose nephropathy?
The ADA changed the terminology, referring to “diabetic kidney disease” (DKD) rather than nephropathy to highlight the fact that the focus is on kidney disease directly linked to diabetes.
Other recommendations include an annual assessment of urinary albumin (eg, spot urine albumin-to-creatinine ratio and eGFR) for patients who have had type 1 diabetes for ≥5 years and all patients who have type 2 diabetes. Two out of 3 abnormal specimens collected within a 3- to 6-month period indicate the presence of albuminuria.
What can be done to prevent or slow the progression of DKD?
Optimal BP and glycemic control are key,29-35 along with diet and medication. For patients with DKD, dietary protein intake should be 0.8 g/kg body weight per day. ACE inhibitors and ARBs have been shown to slow the decline in eGFR in patients with elevated urinary albumin excretion (≥30 mg/day).
However, neither an ACE inhibitor nor an ARB is recommended for the primary prevention of DKD in patients who have normal BP, normal urine albumin-to-creatinine ratio (<30 mg/g), and normal eGFR. In addition, combined use of an ACE inhibitor and an ARB should be avoided, as it provides no additional benefit and increases the risk of adverse effects.29
RETINOPATHY
How should I manage retinopathy in patients with diabetes?
As with the management of DKD, it is important to optimize glycemic and BP control to reduce the risk, or slow the progression, of retinopathy. Intensive diabetes management, with the goal of achieving near-normal glycemic levels, has been shown in large prospective randomized studies to prevent or delay the onset and progression of diabetic retinopathy.33,36 The presence of retinopathy is not a contraindication to aspirin therapy for ASCVD prevention, as aspirin does not increase the risk of retinal hemorrhage.
When should patients with diabetes be screened for retinopathy?
Patients with type 1 diabetes should have an initial dilated and comprehensive eye examination by an ophthalmologist or optometrist within 5 years of the onset of diabetes. Those with type 2 diabetes should have such an exam shortly after diagnosis. The exam should be repeated annually; if there is no evidence of retinopathy, however, 2-year intervals may be considered.
PERIPHERAL NEUROPATHY
When and how should I screen patients with diabetes for neuropathy?
All patients should be screened for diabetic peripheral neuropathy (DPN) starting at diagnosis of type 2 diabetes and 5 years after the diagnosis of type 1 diabetes, and continued at least annually thereafter. Assessment should include a detailed history and 10-g monofilament testing, as well as at least one of the following tests: pinprick, temperature, and vibration sensation.
It is important, too, to screen patients with more advanced diabetes for signs and symptoms of autonomic neuropathy. Signs and symptoms may include resting tachycardia, exercise intolerance, orthostatic hypotension, gastroparesis, constipation, impaired neurovascular function, and autonomic failure in response to hypoglycemia. In men, diabetic autonomic neuropathy may cause erectile dysfunction and/or retrograde ejaculation.
How should I manage patients who have DPN?
Tight glycemic control is the only measure that has been shown to prevent or delay the development of DPN or cardiac autonomic neuropathy in patients with type 1 diabetes,37,38 and to slow the progression of neuropathy in some patients with type 2 diabetes.39
The FDA has approved pregabalin, duloxetine, and tapentadol for the treatment of pain associated with DPN. Tricyclic antidepressants, gabapentin, venlafaxine, carbamazepine, tramadol, and topical capsaicin, although not approved for the treatment of painful DPN, may also be effective in treating neuropathic pain.
For those with autonomic neuropathy, dietary changes and prokinetic agents such as erythromycin may alleviate gastroparesis. Due to extrapyramidal adverse effects, metoclopramide is reserved for the most severe and unresponsive cases. Recurrent urinary tract infections, pyelonephritis, incontinence, or palpable bladder should prompt an evaluation for bladder dysfunction. Controlling lipids and BP, quitting smoking, and making other lifestyle changes can reduce both the development and the progression of autonomic neuropathy.
FOOT CARE/PERIPHERAL ARTERIAL DISEASE
What does the ADA recommend regarding foot care for patients with diabetes?
The ADA’s standards recommend an annual comprehensive foot examination to identify risk factors predictive of ulcers and potential amputations. The exam should start with inspection and assessment of foot pulses and should seek to identify loss of peripheral sensation. The examination should include inspection of the skin, assessment of foot deformities, neurologic assessment including 10-g monofilament testing and pinprick or vibration testing or assessment of ankle reflexes, and vascular assessment, including pulses in the legs and feet.40
It is also important to screen patients for peripheral arterial disease (PAD), with a comprehensive medical history and physical exam of pulses. Ankle-brachial index testing (ABI) should be performed in patients with signs or symptoms of PAD, including claudication or skin and hair changes in the lower extremities. ABI may be considered for all patients with diabetes starting at age 50 and in those younger than 50 years who have risk factors.41
Which patients with diabetes are at higher risk for foot complications?
The following are risk factors for foot complications: previous amputation, prior foot ulcer, peripheral neuropathy, foot deformity, peripheral vascular disease, visual impairment, peripheral neuropathy (especially if on dialysis), poor glycemic control, and smoking. Patients with high-risk foot conditions should be educated about their risk and appropriate management.
A well-fitted walking shoe that cushions the feet and redistributes pressure is one option to help patients. Patients with bony deformities may need extra wide or deep shoes and patients with more advanced disease may need custom-fitted shoes.
When should patients be referred to a foot specialist?
Refer patients to a foot care specialist for ongoing preventive care and lifelong surveillance if they smoke or have a history of lower-extremity complications, a loss of protective sensation, structural abnormalities, or PAD.
1. American Diabetes Association. Standards of Medical Care in Diabetes—2016. Diabetes Care. 2016;39(Suppl 1). Available at: http://care.diabetesjournals.org/site/misc/2016-Standards-of-Care.pdf. Accessed March 28, 2016.
2. International Expert Committee Report on the role of the A1C assay in the diagnosis of diabetes. Diabetes Care. 2009;32:1327-1334.
3. Lipska KJ, Ross JS, Miao Y, et al. Potential overtreatment of diabetes mellitus in older adults with tight glycemic control. JAMA Intern Med. 2015;175:356–362.
4. Vijan S, Sussman JB, Yudkin JS, et al. Effect of patients’ risks and p on health gains with plasma glucose level lowering in type 2 diabetes mellitus. JAMA Intern Med. 2014;174:1227–1234.
5. Knowler WC, Barrett-Connor E, Fowler SE, et al; Diabetes Prevention Program Research Group. Reduction in the incidence of type 2 diabetes with lifestyle intervention or metformin. N Engl J Med. 2002;346:393–403.
6. Diabetes Prevention Program Research Group. Long-term safety, tolerability, and weight loss associated with metformin in the Diabetes Prevention Program Outcomes Study. Diabetes Care. 2012;35:731–737.
7. UK Prospective Diabetes Study 7: response of fasting plasma glucose to diet therapy in newly presenting type II diabetic patients, UKPDS Group. Metabolism. 1990;39:905–912.
8. Goldstein DJ. Beneficial health effects of modest weight loss. Int J Obes Relat Metab Disord. 1992;16:397–415.
9. Pastors JG, Warshaw H, Daly A, et al. The evidence for the effectiveness of medical nutrition therapy in diabetes management. Diabetes Care. 2002;25:608–613.
10. Selph S, Dana T, Bougatsos C, et al. Screening for abnormal glucose and type 2 diabetes mellitus: a systematic review to update the 2008 US Preventive Services Task Force Recommendation. Available at: http://www.ncbi.nlm.nih.gov/books/NBK293871/. Accessed March 28, 2016.
11. Tsai AG, Wadden TA. The evolution of very-low-calorie diets: an update and metaanalysis. Obesity (Silver Spring). 2006;14:1283–1293.
12. Johansson K, Neovius M, Hemmingsson E. Effects of anti-obesity drugs, diet, and exercise on weight-loss maintenance after a very low-calorie diet or low-calorie diet: a systematic review and meta-analysis of randomized controlled trials. Am J Clin Nutr. 2014;99:14–23.
13. Inzucchi SE, Bergenstal RM, Buse JB, et al. Management of hyperglycemia in type 2 diabetes, 2015: a patient-centered approach. Update to a position statement of the American Diabetes Association and the European Association for the Study of Diabetes. Diabetes Care. 2015;38:140–149.
14. Singh S, Loke YK, Furberg CD. Long-term risk of cardiovascular events with rosiglitazone: a meta-analysis. JAMA. 2007;298:1189–1195.
15. Balaji V, Seshiah V, Ashtalakshmi G, et al. Retrospective study on finding correlation of pioglitazone and incidences of bladder cancer in the Indian population. Indian J Endocrinol Metab. 2014;18:425–427.
16. Kuo HW, Tiao MM, Ho SC, et al. Pioglitazone use and the risk of bladder cancer. Kaohsiung J Med Sci. 2014;30:94–97.
17. Wei L, MacDonald TM, Mackenzie IS. Pioglitazone and bladder cancer: a propensity score matched cohort study. Br J Clin Pharmacol. 2013;75:254-259.
18. US Food and Drug Administration. FDA Drug Safety Communication: FDA revises labels of SGLT2 inhibitors for diabetes to include warnings about too much acid in the blood and serious urinary tract infections. 2015. Available at: http://www.fda.gov/Drugs/DrugSafety/ucm475463.htm. Accessed December 11, 2015.
19. Huxley RR, Peters SAE, Mishra GD, et al. Risk of all-cause mortality and vascular events in women versus men with type 1 diabetes: a systematic review and meta-analysis. Lancet Diabetes Endocrinol. 2015;3:198–206.
20. Peters SA, Huxley RR, Woodward M. Diabetes as risk factor for incident coronary heart disease in women compared with men: a systematic review and meta-analysis of 64 cohorts including 858,507 individuals and 28,203 coronary events. Diabetologia. 2014;57:1542–1551.
21. Peters SA, Huxley RR, Woodward M. Diabetes as a risk factor for stroke in women compared with men: a systematic review and meta-analysis of 64 cohorts, including 775,385 individuals and 12,539 strokes. Lancet. 2014;383:1973-1980.
22. Cushman WC, Evans GW, Byington RP, et al; ACCORD Study Group. Effects of intensive blood-pressure control in type 2 diabetes mellitus. N Engl J Med. 2010;362:1575–1585.
23. Cannon CP, Blazing MA, Giugliano RP, et al; IMPROVE-IT Investigators. Ezetimibe added to statin therapy after acute coronary syndromes. N Engl J Med. 2015;372:2387–2397.
24. Knopp RH, d’Emden M, Smilde JG, et al. Efficacy and safety of atorvastatin in the prevention of cardiovascular end points in subjects with type 2 diabetes: the Atorvastatin Study for Prevention of Coronary Heart Disease Endpoints in non-insulin-dependent diabetes mellitus (ASPEN). Diabetes Care. 2006;29:1478–1485.
25. Colhoun HM, Betteridge DJ, Durrington PN, et al; CARDS Investigators. Primary prevention of cardiovascular disease with atorvastatin in type 2 diabetes in the Collaborative Atorvastatin Diabetes Study (CARDS): multicentre randomised placebo-controlled trial. Lancet. 2004;364:685–696.
26. Cannon CP, Braunwald E, McCabe CH, et al; Pravastatin or Atorvastatin Evaluation and Infection Therapy-Thrombolysis in Myocardial Infarction 22 Investigators. Intensive versus moderate lipid lowering with statins after acute coronary syndromes. N Engl J Med. 2004;350:1495–1504.
27. de Lemos JA, Blazing MA, Wiviott SD, et al. Early intensive vs a delayed conservative simvastatin strategy in patients with acute coronary syndromes: phase Z of the A to Z trial. JAMA. 2004;292:1307–1316.
28. Nissen SE, Tuzcu EM, Schoenhagen P, et al; REVERSAL Investigators. Effect of intensive compared with moderate lipid-lowering therapy on progression of coronary atherosclerosis: a randomized controlled trial. JAMA. 2004;291:1071–1080.
29. UK Prospective Diabetes Study Group. Tight blood pressure control and risk of macrovascular and microvascular complications in type 2 diabetes: UKPDS 38. BMJ. 1998;317:703–713.
30. Tuttle KR, Bakris GL, Bilous RW, et al. Diabetic kidney disease: a report from an American Diabetes Association Consensus Conference. Diabetes Care. 2014;37:2864–2883.
31. The Diabetes Control and Complications (DCCT) Research Group. Effect of intensive therapy on the development and progression of diabetic nephropathy in the Diabetes Control and Complications Trial. Kidney Int. 1995;47:1703–1720.
32. UK Prospective Diabetes Study (UKPDS) Group. Effect of intensive blood-glucose control with metformin on complications in overweight patients with type 2 diabetes (UKPDS 34). Lancet. 1998;352:854–865.
33. UK Prospective Diabetes Study (UKPDS) Group. Intensive blood-glucose control with sulphonylureas or insulin compared with conventional treatment and risk of complications in patients with type 2 diabetes (UKPDS 33). Lancet. 1998;352:837–853.
34. Patel A, MacMahon S, Chalmers J, et al; ADVANCE Collaborative Group. Intensive blood glucose control and vascular outcomes in patients with type 2 diabetes. N Engl J Med. 2008;358:2560–2572.
35. Ismail-Beigi F, Craven T, Banerji MA, et al; ACCORD Trial Group. Effect of intensive treatment of hyperglycaemia on microvascular outcomes in type 2 diabetes: an analysis of the ACCORD randomised trial. Lancet. 2010;376:419–430.
36. Yusuf S, Teo KK, Pogue J, et al; ONTARGET Investigators. Telmisartan, ramipril, or both in patients at high risk for vascular events. N Engl J Med. 2008;358:1547–1559.
37. Chew EY, Ambrosius WT, Davis MD, et al; ACCORD Study Group; ACCORD Eye Study Group. Effects of medical therapies on retinopathy progression in type 2 diabetes. N Engl J Med. 2010;363:233–244.
38. Ang L, Jaiswal M, Martin C, et al. Glucose control and diabetic neuropathy: lessons from recent large clinical trials. Curr Diab Rep. 2014;14:528.
39. Martin CL, Albers JW, Pop-Busui R; DCCT/EDIC Research Group. Neuropathy and related findings in the Diabetes Control and Complications Trial/Epidemiology of Diabetes Interventions and Complications study. Diabetes Care. 2014;37:31–38.
40. Bril V, England J, Franklin GM, et al; American Academy of Neurology; American Association of Neuromuscular and Electrodiagnostic Medicine; American Academy of Physical Medicine and Rehabilitation. Evidence-based guideline: treatment of painful diabetic neuropathy: report of the American Academy of Neurology, the American Association of Neuromuscular and Electrodiagnostic Medicine, and the American Academy of Physical Medicine and Rehabilitation. Neurology. 2011;76:1758–1765.
41. American Diabetes Association. Peripheral arterial disease in people with diabetes. Diabetes Care. 2003;26:3333–3341.
42. Centers for Disease Control and Prevention. Recommended adult immunization schedule for adults aged 19 years or older, by vaccine and age group. United States, 2016. Available at: http://www.cdc.gov/vaccines/schedules/hcp/imz/adult.html. Accessed April 8, 2016.
1. American Diabetes Association. Standards of Medical Care in Diabetes—2016. Diabetes Care. 2016;39(Suppl 1). Available at: http://care.diabetesjournals.org/site/misc/2016-Standards-of-Care.pdf. Accessed March 28, 2016.
2. International Expert Committee Report on the role of the A1C assay in the diagnosis of diabetes. Diabetes Care. 2009;32:1327-1334.
3. Lipska KJ, Ross JS, Miao Y, et al. Potential overtreatment of diabetes mellitus in older adults with tight glycemic control. JAMA Intern Med. 2015;175:356–362.
4. Vijan S, Sussman JB, Yudkin JS, et al. Effect of patients’ risks and p on health gains with plasma glucose level lowering in type 2 diabetes mellitus. JAMA Intern Med. 2014;174:1227–1234.
5. Knowler WC, Barrett-Connor E, Fowler SE, et al; Diabetes Prevention Program Research Group. Reduction in the incidence of type 2 diabetes with lifestyle intervention or metformin. N Engl J Med. 2002;346:393–403.
6. Diabetes Prevention Program Research Group. Long-term safety, tolerability, and weight loss associated with metformin in the Diabetes Prevention Program Outcomes Study. Diabetes Care. 2012;35:731–737.
7. UK Prospective Diabetes Study 7: response of fasting plasma glucose to diet therapy in newly presenting type II diabetic patients, UKPDS Group. Metabolism. 1990;39:905–912.
8. Goldstein DJ. Beneficial health effects of modest weight loss. Int J Obes Relat Metab Disord. 1992;16:397–415.
9. Pastors JG, Warshaw H, Daly A, et al. The evidence for the effectiveness of medical nutrition therapy in diabetes management. Diabetes Care. 2002;25:608–613.
10. Selph S, Dana T, Bougatsos C, et al. Screening for abnormal glucose and type 2 diabetes mellitus: a systematic review to update the 2008 US Preventive Services Task Force Recommendation. Available at: http://www.ncbi.nlm.nih.gov/books/NBK293871/. Accessed March 28, 2016.
11. Tsai AG, Wadden TA. The evolution of very-low-calorie diets: an update and metaanalysis. Obesity (Silver Spring). 2006;14:1283–1293.
12. Johansson K, Neovius M, Hemmingsson E. Effects of anti-obesity drugs, diet, and exercise on weight-loss maintenance after a very low-calorie diet or low-calorie diet: a systematic review and meta-analysis of randomized controlled trials. Am J Clin Nutr. 2014;99:14–23.
13. Inzucchi SE, Bergenstal RM, Buse JB, et al. Management of hyperglycemia in type 2 diabetes, 2015: a patient-centered approach. Update to a position statement of the American Diabetes Association and the European Association for the Study of Diabetes. Diabetes Care. 2015;38:140–149.
14. Singh S, Loke YK, Furberg CD. Long-term risk of cardiovascular events with rosiglitazone: a meta-analysis. JAMA. 2007;298:1189–1195.
15. Balaji V, Seshiah V, Ashtalakshmi G, et al. Retrospective study on finding correlation of pioglitazone and incidences of bladder cancer in the Indian population. Indian J Endocrinol Metab. 2014;18:425–427.
16. Kuo HW, Tiao MM, Ho SC, et al. Pioglitazone use and the risk of bladder cancer. Kaohsiung J Med Sci. 2014;30:94–97.
17. Wei L, MacDonald TM, Mackenzie IS. Pioglitazone and bladder cancer: a propensity score matched cohort study. Br J Clin Pharmacol. 2013;75:254-259.
18. US Food and Drug Administration. FDA Drug Safety Communication: FDA revises labels of SGLT2 inhibitors for diabetes to include warnings about too much acid in the blood and serious urinary tract infections. 2015. Available at: http://www.fda.gov/Drugs/DrugSafety/ucm475463.htm. Accessed December 11, 2015.
19. Huxley RR, Peters SAE, Mishra GD, et al. Risk of all-cause mortality and vascular events in women versus men with type 1 diabetes: a systematic review and meta-analysis. Lancet Diabetes Endocrinol. 2015;3:198–206.
20. Peters SA, Huxley RR, Woodward M. Diabetes as risk factor for incident coronary heart disease in women compared with men: a systematic review and meta-analysis of 64 cohorts including 858,507 individuals and 28,203 coronary events. Diabetologia. 2014;57:1542–1551.
21. Peters SA, Huxley RR, Woodward M. Diabetes as a risk factor for stroke in women compared with men: a systematic review and meta-analysis of 64 cohorts, including 775,385 individuals and 12,539 strokes. Lancet. 2014;383:1973-1980.
22. Cushman WC, Evans GW, Byington RP, et al; ACCORD Study Group. Effects of intensive blood-pressure control in type 2 diabetes mellitus. N Engl J Med. 2010;362:1575–1585.
23. Cannon CP, Blazing MA, Giugliano RP, et al; IMPROVE-IT Investigators. Ezetimibe added to statin therapy after acute coronary syndromes. N Engl J Med. 2015;372:2387–2397.
24. Knopp RH, d’Emden M, Smilde JG, et al. Efficacy and safety of atorvastatin in the prevention of cardiovascular end points in subjects with type 2 diabetes: the Atorvastatin Study for Prevention of Coronary Heart Disease Endpoints in non-insulin-dependent diabetes mellitus (ASPEN). Diabetes Care. 2006;29:1478–1485.
25. Colhoun HM, Betteridge DJ, Durrington PN, et al; CARDS Investigators. Primary prevention of cardiovascular disease with atorvastatin in type 2 diabetes in the Collaborative Atorvastatin Diabetes Study (CARDS): multicentre randomised placebo-controlled trial. Lancet. 2004;364:685–696.
26. Cannon CP, Braunwald E, McCabe CH, et al; Pravastatin or Atorvastatin Evaluation and Infection Therapy-Thrombolysis in Myocardial Infarction 22 Investigators. Intensive versus moderate lipid lowering with statins after acute coronary syndromes. N Engl J Med. 2004;350:1495–1504.
27. de Lemos JA, Blazing MA, Wiviott SD, et al. Early intensive vs a delayed conservative simvastatin strategy in patients with acute coronary syndromes: phase Z of the A to Z trial. JAMA. 2004;292:1307–1316.
28. Nissen SE, Tuzcu EM, Schoenhagen P, et al; REVERSAL Investigators. Effect of intensive compared with moderate lipid-lowering therapy on progression of coronary atherosclerosis: a randomized controlled trial. JAMA. 2004;291:1071–1080.
29. UK Prospective Diabetes Study Group. Tight blood pressure control and risk of macrovascular and microvascular complications in type 2 diabetes: UKPDS 38. BMJ. 1998;317:703–713.
30. Tuttle KR, Bakris GL, Bilous RW, et al. Diabetic kidney disease: a report from an American Diabetes Association Consensus Conference. Diabetes Care. 2014;37:2864–2883.
31. The Diabetes Control and Complications (DCCT) Research Group. Effect of intensive therapy on the development and progression of diabetic nephropathy in the Diabetes Control and Complications Trial. Kidney Int. 1995;47:1703–1720.
32. UK Prospective Diabetes Study (UKPDS) Group. Effect of intensive blood-glucose control with metformin on complications in overweight patients with type 2 diabetes (UKPDS 34). Lancet. 1998;352:854–865.
33. UK Prospective Diabetes Study (UKPDS) Group. Intensive blood-glucose control with sulphonylureas or insulin compared with conventional treatment and risk of complications in patients with type 2 diabetes (UKPDS 33). Lancet. 1998;352:837–853.
34. Patel A, MacMahon S, Chalmers J, et al; ADVANCE Collaborative Group. Intensive blood glucose control and vascular outcomes in patients with type 2 diabetes. N Engl J Med. 2008;358:2560–2572.
35. Ismail-Beigi F, Craven T, Banerji MA, et al; ACCORD Trial Group. Effect of intensive treatment of hyperglycaemia on microvascular outcomes in type 2 diabetes: an analysis of the ACCORD randomised trial. Lancet. 2010;376:419–430.
36. Yusuf S, Teo KK, Pogue J, et al; ONTARGET Investigators. Telmisartan, ramipril, or both in patients at high risk for vascular events. N Engl J Med. 2008;358:1547–1559.
37. Chew EY, Ambrosius WT, Davis MD, et al; ACCORD Study Group; ACCORD Eye Study Group. Effects of medical therapies on retinopathy progression in type 2 diabetes. N Engl J Med. 2010;363:233–244.
38. Ang L, Jaiswal M, Martin C, et al. Glucose control and diabetic neuropathy: lessons from recent large clinical trials. Curr Diab Rep. 2014;14:528.
39. Martin CL, Albers JW, Pop-Busui R; DCCT/EDIC Research Group. Neuropathy and related findings in the Diabetes Control and Complications Trial/Epidemiology of Diabetes Interventions and Complications study. Diabetes Care. 2014;37:31–38.
40. Bril V, England J, Franklin GM, et al; American Academy of Neurology; American Association of Neuromuscular and Electrodiagnostic Medicine; American Academy of Physical Medicine and Rehabilitation. Evidence-based guideline: treatment of painful diabetic neuropathy: report of the American Academy of Neurology, the American Association of Neuromuscular and Electrodiagnostic Medicine, and the American Academy of Physical Medicine and Rehabilitation. Neurology. 2011;76:1758–1765.
41. American Diabetes Association. Peripheral arterial disease in people with diabetes. Diabetes Care. 2003;26:3333–3341.
42. Centers for Disease Control and Prevention. Recommended adult immunization schedule for adults aged 19 years or older, by vaccine and age group. United States, 2016. Available at: http://www.cdc.gov/vaccines/schedules/hcp/imz/adult.html. Accessed April 8, 2016.
