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Pediatric Dermatology: A Supplement to Pediatric News & Dermatology News
Content includes:
- Early onset of atopic dermatitis linked to poorer control, could signify more persistent disease
- Patients with actopic dermatitis should be routinely asked about conjunctivitis
- Hope on the horizon: New cantharidin formulation alleviates molluscum contagiosum in pivotal trials
- Patch testing in atopic dermatitis: When and how
- Topical calcineurin inhibitors are an effective treatment option for periorificial dermatitis
- Psychology consults for children’s skin issues can boost adherence, wellness
Content includes:
- Early onset of atopic dermatitis linked to poorer control, could signify more persistent disease
- Patients with actopic dermatitis should be routinely asked about conjunctivitis
- Hope on the horizon: New cantharidin formulation alleviates molluscum contagiosum in pivotal trials
- Patch testing in atopic dermatitis: When and how
- Topical calcineurin inhibitors are an effective treatment option for periorificial dermatitis
- Psychology consults for children’s skin issues can boost adherence, wellness
Content includes:
- Early onset of atopic dermatitis linked to poorer control, could signify more persistent disease
- Patients with actopic dermatitis should be routinely asked about conjunctivitis
- Hope on the horizon: New cantharidin formulation alleviates molluscum contagiosum in pivotal trials
- Patch testing in atopic dermatitis: When and how
- Topical calcineurin inhibitors are an effective treatment option for periorificial dermatitis
- Psychology consults for children’s skin issues can boost adherence, wellness
Infectious Diseases Board Review: Menopause in Women Living With HIV
More than half of the 37.9 million persons living with HIV (PLWH) worldwide are women.1 Between 2010 and 2016, 58% of women living with HIV (WLWH) in the United States were older than 45 years.2 As such, an increasing number of WLWH are entering menopause and living well beyond menopause. Despite this, health care providers expressed a lack of confidence in managing menopause in WLWH, and menopausal symptoms often are not recognized by providers.3 Enhancing our knowledge about menopause in WLWH is important, since the physiologic changes associated with menopause impact short- and long-term quality of life and mortality.
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Amenorrhea
Menstrual irregularities, including amenorrhea and anovulation, are more frequently found in women of low socioeconomic status, presumably due to associated physical and emotional stress.4 In addition, women with low body mass index (BMI) have decreased serum estradiol levels, which lead to amenorrhea.4,5 Furthermore, low parity and many legal and illegal drugs are associated with amenorrhea, including hormonal contraceptives, opiates, stimulants, antipsychotics, and chemotherapeutic agents.6-8
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Age at Menopause
In the United States, the median age of menopause is between 50 and 52 years in middle-class white women.11,12 Earlier menopause has been observed in women who are African American, are nulliparous, have a lower BMI, smoke tobacco, and have more stress, less education, and higher unemployment rates.11,13,14 Because 57% of women diagnosed with HIV in 2018 were African American and many WLWH have other risk factors associated with earlier menopause, studies examining the age of menopause in WLWH need to use a comparator group of women without HIV with similar characteristics and control for these factors to determine the influence of HIV on the age of menopause.
Menopause-Associated Symptoms
The perimenopausal period, which begins, on average, 4 years prior to the final menstrual period, is characterized by hormonal fluctuations leading to irregular menstrual cycles.19,20 Symptoms associated with these physiologic changes during the perimenopausal period include vasomotor symptoms (hot flashes), genitourinary symptoms (vaginal dryness and dyspareunia), anxiety, depression, sleep disturbances, and joint aches.21,22 Such menopausal symptoms can be distressing and negatively impact quality of life.23 In WLWH, severe menopausal symptoms have been associated with suboptimal adherence to antiretroviral therapy (ART).24
Vasomotor
In the United States, the most common symptom during perimenopause is hot flashes, which occur in 38% to 80% of women.32,33 Vasomotor symptoms are most common in women who smoke, use illicit substances, have a high BMI, are of lower socioeconomic status, and are African American.11 As expected, prior studies focusing on hot flash prevalence among premenopausal, perimenopausal, and postmenopausal WLWH found that postmenopausal women experience more hot flashes than premenopausal or perimenopausal women.27,28 In addition, a comparison of women with and without HIV demonstrated a higher prevalence of hot flashes among WLWH.26,29 Vasomotor symptoms can be severely distressing, with hot flashes contributing to increased risk of depression.25,34 In a cross-sectional analysis of 835 WLWH and 335 women without HIV from the WIHS cohort, persistent vasomotor symptoms predicted elevated depressive symptoms in both WLWH and women without HIV.34 In a similar cross-sectional analysis of 536 women, among whom 54% were WLWH and 37% were perimenopausal, psychological symptoms were prevalent in 61% of the women with vasomotor symptoms.29
Genitourinary
Estrogen deficiency, which accompanies the perimenopausal period, leads to vulvovaginal atrophy (VVA), manifesting with symptoms of vaginal dryness, itching, burning, urinary urgency, and dyspareunia (painful intercourse).33,35,36 Unlike vasomotor symptoms, which diminish with time, genitourinary symptoms generally worsen if left untreated.37 Furthermore, these symptoms are often underreported and underdiagnosed.38,39 VVA was found in 43% to 84% of postmenopausal women.36,40,41 In the AGATA study, the prevalence of VVA was associated with years since menopause. 36 Vaginal dryness and dyspareunia were common.
Psychiatric
Anxiety and depression are also common symptoms in perimenopausal women.46-48 Studies have shown that depression is diagnosed 2.5 times more frequently among perimenopausal women than premenopausal women.48 In a study by Miller et al that focused on 536 WLWH, among whom 37% were perimenopausal, 89% reported psychological symptoms.29 Ferreira et al found that perimenopausal WLWH had an increased incidence of psychological symptoms, such as depression and anxiety, compared to women without HIV infection.26 Whether this increased prevalence of psychological symptoms seen in WLWH can be attributed to menopause is unclear, since one third to one half of men and women living with HIV experience symptoms of depression.49 However, in the WIHS, which compared findings from 835 WLWH to findings from 335 women without HIV from all menopausal stages, elevated depressive symptoms were seen in the early perimenopausal period.34 There was no increased incidence of such symptoms during the premenopausal or postmenopausal stage, suggesting that factors related to menopause contribute to depressive symptoms during the perimenopausal stage.34
Other Symptoms
Sleep disturbances are common among perimenopausal women, with an estimated prevalence between 38% and 46%.52-54 Hot flashes, anxiety, and depression appear to be factors that contribute to sleep difficulty.52-54 In a cross-sectional study of 273 WLWH and 264 women without HIV between 40 and 60 years of age, insomnia was found in 51% of perimenopausal and 53% of postmenopausal WLWH. The prevalence of insomnia in WLWH and women without HIV was the same.55 Joint aches are also commonly reported in the perimenopausal period, with a prevalence as high as 50% to 60% among perimenopausal women in the United States.22,29 Miller and colleagues found that 63% of menopausal WLWH reported arthralgia.29
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Treatment
Despite the increased severity of menopausal symptoms experienced among WLWH, menopausal replacement therapy (MRT) is used less frequently in WLWH than in women living without HIV.55 Topical treatment is recommended for women who are experiencing vaginal dryness. First-line treatment is topical nonhormonal therapy, such as moisturizers and lubricants.56 If symptoms are not relieved, then topical vaginal estrogen therapy is recommended.56 Randomized placebo-controlled studies have verified the safety and efficacy of topical estrogen in the general population, and there is no reason to expect different outcomes in WLWH.57,58
Cardiovascular Risk
Estrogen deficiency that occurs during menopause leads to an increased risk of cardiovascular disease, particularly with changes in lipid profiles, insulin resistance, and body composition (eg, increased fat mass and waist circumference).61 HIV infection also is associated with a higher risk of cardiovascular disease, with studies consistently reporting a 1.5- to 2-fold increase in the rate of cardiovascular events in PLWH compared to persons without HIV.62 The inflammatory effects of HIV as well as ART exposure, specifically to PIs and abacavir, increase the risk for cardiovascular disease.62 In addition, traditional risk factors, including dyslipidemia, contribute to cardiovascular disease risk in this population.63,64
Osteoporosis
Menopause, with its associated estrogen deficiency, is the most important risk factor linked to increased bone turnover and bone loss.70 In addition, HIV is associated with bone loss, with low bone mineral density (BMD) described even among men and premenopausal women with HIV infection.71 Although decreased BMD associated with HIV stabilizes or even improves after initiation of ART in the younger population,72-74 chronic inflammation caused by HIV stimulates osteoclast differentiation and resorption.71 Other factors that appear to contribute to decreased BMD among PLWH include ART; vitamin D deficiency; low BMI; poor nutrition; inactivity; use of tobacco, alcohol, and illicit drugs; hepatitis B and C coinfection; and frailty, defined as increased vulnerability to stresses related to aging.72-80 Among ARTs, tenofovir disoproxil fumarate is associated with an increased risk of osteoporosis, and switching from this agent to tenofovir alafenamide improves bone density.81 Prolonged amenorrhea is also an added risk factor for osteoporosis in WLWH.82
Cognition
Both men and women living with HIV are at higher risk for cognitive impairment, ranging from minor cognitive-motor disorder to HIV-associated dementia.91 In addition, the menopause transition is characterized by cognitive changes, such as memory loss and difficulty concentrating.92,93 Studies focusing on the effects of both HIV infection and menopause on cognition have been limited thus far. A cross-sectional study demonstrated that HIV infection, but not menopausal stage, was associated with worse performance on cognitive measures.94 While menopausal stage was not associated with cognitive decline, menopausal symptoms like depression, anxiety, and vasomotor symptoms were associated with lower cognitive performance, highlighting the importance of recognition and treatment of menopausal symptoms.94
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Cervical Dysplasia
WLWH are at increased risk for low- and high-grade squamous intraepithelial lesions (SILs) and more rapid progression to cervical carcinoma, as compared to women without HIV.95 This increased risk of cervical disease is associated with age, human papillomavirus genotype, and degree of immunosuppression.96 In addition, menopause appears to affect the risk of cervical disease. Postmenopausal WLWH had a higher risk of progression of SILs and persistence of lower-grade SILs compared to premenopausal women.97,98 Although studies on progression to cervical cancer in postmenopausal WLWH remain limited, current data suggest that postmenopausal WLWH should continue to be monitored and screened similarly to premenopausal women.
HIV Acquisition and Transmission
Women aged 50 years and older are primarily exposed to HIV through heterosexual contact.99 While the lack of awareness of HIV risk and less frequent use of barrier protection can contribute to new HIV infection in older women, physiologic changes associated with menopause also may be playing a role.100 Vaginal wall thinning and immunologic changes of the cervix that occur during menopause may serve as a risk factor for HIV acquisition. The cervicovaginal mucosa of postmenopausal women had higher levels of p24 antigen after ex vivo HIV-1 infection, suggesting higher susceptibility to acquire HIV infection.101 Postmenopausal women have been shown to have increased cervical CCR5 expression, which serves as an entry point of HIV into target cells.102 Finally, anti-HIV-1 activity was significantly decreased in postmenopausal women compared to premenopausal women.103 In addition, ex vivo studies demonstrated reduced tenofovir disoproxil fumarate and emtricitabine triphosphate concentrations in cervical tissue of postmenopausal women, suggesting that postmenopausal women may need higher doses of pre-exposure prophylaxis to achieve protective efficacy.104
HIV Progression
With prior data suggesting that younger persons experience better immunologic and virologic responses to ART,107-109 it had previously been hypothesized that virologic and immunologic responses to ART will decline once WLWH reach menopause. However, current studies suggest that menopause does not affect the progression of HIV and that ART-naive women should respond to ART, regardless of their menopausal status. Treatment responses to ART, determined by the median changes in CD4 cell counts and percentages and viral load, in ART-naive individuals did not differ between premenopausal and postmenopausal women.110 In addition, there appear to be no significant changes in CD4 cell counts as WLWH progress through menopause.111
Conclusion
As individuals with HIV infection live longer, an increasing number of women will enter menopause and live many years beyond menopause. WLWH experience earlier and more severe menopausal symptoms, but evidence on the appropriate management of these symptoms is still lacking. These conditions require proper surveillance, and can be prevented with an improved understanding of the effects of menopause on WLWH. However, there remain significant gaps in our understanding of menopause in WLWH. As practitioners encounter an increasing number of perimenopausal and postmenopausal WLWH, studies of the effects of HIV on comorbidities and symptoms of menopause and their appropriate management are necessary to improve care of WLWH.
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1. UNAIDS. AIDSInfo. 2019 estimates https://www.unaids.org/en/resources/infographics/girls-and-women-living-with-HIV. Accessed April 30, 2020.
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94. Rubin LH, Sundermann EE, Cook JA, et al. An investigation of menopausal stage and symptoms on cognition in HIV-infected women. Menopause. 2014;21:997-1006.
95. Ellerbrock TV, Chiasson MA, Bush TJ, et al. Incidence of cervical squamous intraepithelial lesions in HIV-infected women. JAMA. 2000;283:1031-1037.
96. Mandelblatt JS, Kanetsky P, Eggert L, et al. Is HIV infection a cofactor for cervical squamous cell neoplasia? Cancer Epidemiol Biomarkers Prev. 1999;8:97-106.
97. Kim SC, Messing S, Shah K, et al. Effects of highly active antiretroviral therapy (HAART) and menopause on risk of progression of cervical dysplasia in human immune deficiency virus (HIV) infected women. Infect Dis Obstet Gynecol. 2013;2013:784718.
98. Ceccaldi PF, Ferreira C, Coussy F, et al. Cervical disease in postmenopausal HIV-1 infected women. J Gynecol Obstet Biol Reprod. 2010;39:466-470.
99. Centers for Disease Control and Prevention. HIV and older Americans. www.cdc.gov/hiv/group/age/olderamericans/index.html. Accessed May 11, 2020.
100. Levy JA, Ory MG, Crystal S. HIV/AIDS interventions for midlife and older adults: current status and challenges. J Acquir Immune Defic Syndr. 2003;33 Suppl 2:S59-S67.
101. Thurman AR, Yousefieh N, Chandra N, et al. Comparison of mucosal markers of human immunodeficiency virus susceptibility in healthy premenopausal versus postmenopausal women. AIDS Res Hum Retroviruses. 2017;33:807-819.
102. Meditz AL, Moreau KL, MaWhinney S, et al. CCR5 expression is elevated on endocervical CD4+ T cells in healthy postmenopausal women. J Acquir Immune Defic Syndr. 2012;59:221-228.
103. Chappell CA, Isaacs CE, Xu W, et al. The effect of menopause on the innate antiviral activity of cervicovaginal lavage. Am J Obstet Gynecol. 2015;213:204.
104. Nicol MR, Brewers LM, Kashuba ADM, et al. The role of menopause in tenofovir diphosphate and emtricitabine triphosphate concentrations in cervical tissue. AIDS. 2018;32:11-15.
105. Melo KC, Melo MR, Ricci BV, Segurado AC. Correlates of human immunodeficiency virus cervicovaginal shedding among postmenopausal and fertile-aged women. Menopause. 2012;19:150-156.
106. Landolt NK, Do T, Kasipong N, et al. Low-level genital HIV shedding in Thai HIV-infected women with suppressed plasma viral load after menopause: a longitudinal study. J Virus Erad. 2017;3:204-207.
107. Viard JP, Mocroft A, Chiesi A, et al. Influence of age of CD4 cell recovery in human immunodeficiency virus-infected patients receiving highly active antiretroviral therapy: evidence from the Euro SIDA study. J Infect Dis. 2001;193:1290-1294.
108. Grabar S, Kousignian I, Sobel A, et al. Immunological and clinical responses to highly active antiretroviral therapy over 50 years of age. Results from the French Hospital Database on HIV. AIDS. 2004;18:2029-2038.
109. Cuzin L, Delpierre C, Gerard S, et al. Immunologic and clinical responses to highly active antiretroviral therapy in patients with HIV infection aged >50 years. Clin Infect Dis. 2007;45:654-657.
110. Patterson KB, Cohn SE, Uynik J, et al. Treatment responses in antiretroviral treatment-naïve premenopausal and postmenopausal HIV-1 infected women: an analysis from AIDS clinical trials group studies. Clin Infect Dis. 2009;49:473476.
111. van Benthem BH, Vernazza P, Coutinho RA, et al. The impact of pregnancy and menopause on CD4 lymphocyte count in HIV-infected women. AIDS. 2002;16:919-922.
More than half of the 37.9 million persons living with HIV (PLWH) worldwide are women.1 Between 2010 and 2016, 58% of women living with HIV (WLWH) in the United States were older than 45 years.2 As such, an increasing number of WLWH are entering menopause and living well beyond menopause. Despite this, health care providers expressed a lack of confidence in managing menopause in WLWH, and menopausal symptoms often are not recognized by providers.3 Enhancing our knowledge about menopause in WLWH is important, since the physiologic changes associated with menopause impact short- and long-term quality of life and mortality.
Test your knowledge of this topic HERE.
Amenorrhea
Menstrual irregularities, including amenorrhea and anovulation, are more frequently found in women of low socioeconomic status, presumably due to associated physical and emotional stress.4 In addition, women with low body mass index (BMI) have decreased serum estradiol levels, which lead to amenorrhea.4,5 Furthermore, low parity and many legal and illegal drugs are associated with amenorrhea, including hormonal contraceptives, opiates, stimulants, antipsychotics, and chemotherapeutic agents.6-8
Test your knowledge of this topic HERE.
Age at Menopause
In the United States, the median age of menopause is between 50 and 52 years in middle-class white women.11,12 Earlier menopause has been observed in women who are African American, are nulliparous, have a lower BMI, smoke tobacco, and have more stress, less education, and higher unemployment rates.11,13,14 Because 57% of women diagnosed with HIV in 2018 were African American and many WLWH have other risk factors associated with earlier menopause, studies examining the age of menopause in WLWH need to use a comparator group of women without HIV with similar characteristics and control for these factors to determine the influence of HIV on the age of menopause.
Menopause-Associated Symptoms
The perimenopausal period, which begins, on average, 4 years prior to the final menstrual period, is characterized by hormonal fluctuations leading to irregular menstrual cycles.19,20 Symptoms associated with these physiologic changes during the perimenopausal period include vasomotor symptoms (hot flashes), genitourinary symptoms (vaginal dryness and dyspareunia), anxiety, depression, sleep disturbances, and joint aches.21,22 Such menopausal symptoms can be distressing and negatively impact quality of life.23 In WLWH, severe menopausal symptoms have been associated with suboptimal adherence to antiretroviral therapy (ART).24
Vasomotor
In the United States, the most common symptom during perimenopause is hot flashes, which occur in 38% to 80% of women.32,33 Vasomotor symptoms are most common in women who smoke, use illicit substances, have a high BMI, are of lower socioeconomic status, and are African American.11 As expected, prior studies focusing on hot flash prevalence among premenopausal, perimenopausal, and postmenopausal WLWH found that postmenopausal women experience more hot flashes than premenopausal or perimenopausal women.27,28 In addition, a comparison of women with and without HIV demonstrated a higher prevalence of hot flashes among WLWH.26,29 Vasomotor symptoms can be severely distressing, with hot flashes contributing to increased risk of depression.25,34 In a cross-sectional analysis of 835 WLWH and 335 women without HIV from the WIHS cohort, persistent vasomotor symptoms predicted elevated depressive symptoms in both WLWH and women without HIV.34 In a similar cross-sectional analysis of 536 women, among whom 54% were WLWH and 37% were perimenopausal, psychological symptoms were prevalent in 61% of the women with vasomotor symptoms.29
Genitourinary
Estrogen deficiency, which accompanies the perimenopausal period, leads to vulvovaginal atrophy (VVA), manifesting with symptoms of vaginal dryness, itching, burning, urinary urgency, and dyspareunia (painful intercourse).33,35,36 Unlike vasomotor symptoms, which diminish with time, genitourinary symptoms generally worsen if left untreated.37 Furthermore, these symptoms are often underreported and underdiagnosed.38,39 VVA was found in 43% to 84% of postmenopausal women.36,40,41 In the AGATA study, the prevalence of VVA was associated with years since menopause. 36 Vaginal dryness and dyspareunia were common.
Psychiatric
Anxiety and depression are also common symptoms in perimenopausal women.46-48 Studies have shown that depression is diagnosed 2.5 times more frequently among perimenopausal women than premenopausal women.48 In a study by Miller et al that focused on 536 WLWH, among whom 37% were perimenopausal, 89% reported psychological symptoms.29 Ferreira et al found that perimenopausal WLWH had an increased incidence of psychological symptoms, such as depression and anxiety, compared to women without HIV infection.26 Whether this increased prevalence of psychological symptoms seen in WLWH can be attributed to menopause is unclear, since one third to one half of men and women living with HIV experience symptoms of depression.49 However, in the WIHS, which compared findings from 835 WLWH to findings from 335 women without HIV from all menopausal stages, elevated depressive symptoms were seen in the early perimenopausal period.34 There was no increased incidence of such symptoms during the premenopausal or postmenopausal stage, suggesting that factors related to menopause contribute to depressive symptoms during the perimenopausal stage.34
Other Symptoms
Sleep disturbances are common among perimenopausal women, with an estimated prevalence between 38% and 46%.52-54 Hot flashes, anxiety, and depression appear to be factors that contribute to sleep difficulty.52-54 In a cross-sectional study of 273 WLWH and 264 women without HIV between 40 and 60 years of age, insomnia was found in 51% of perimenopausal and 53% of postmenopausal WLWH. The prevalence of insomnia in WLWH and women without HIV was the same.55 Joint aches are also commonly reported in the perimenopausal period, with a prevalence as high as 50% to 60% among perimenopausal women in the United States.22,29 Miller and colleagues found that 63% of menopausal WLWH reported arthralgia.29
Test your knowledge of this topic HERE.
Treatment
Despite the increased severity of menopausal symptoms experienced among WLWH, menopausal replacement therapy (MRT) is used less frequently in WLWH than in women living without HIV.55 Topical treatment is recommended for women who are experiencing vaginal dryness. First-line treatment is topical nonhormonal therapy, such as moisturizers and lubricants.56 If symptoms are not relieved, then topical vaginal estrogen therapy is recommended.56 Randomized placebo-controlled studies have verified the safety and efficacy of topical estrogen in the general population, and there is no reason to expect different outcomes in WLWH.57,58
Cardiovascular Risk
Estrogen deficiency that occurs during menopause leads to an increased risk of cardiovascular disease, particularly with changes in lipid profiles, insulin resistance, and body composition (eg, increased fat mass and waist circumference).61 HIV infection also is associated with a higher risk of cardiovascular disease, with studies consistently reporting a 1.5- to 2-fold increase in the rate of cardiovascular events in PLWH compared to persons without HIV.62 The inflammatory effects of HIV as well as ART exposure, specifically to PIs and abacavir, increase the risk for cardiovascular disease.62 In addition, traditional risk factors, including dyslipidemia, contribute to cardiovascular disease risk in this population.63,64
Osteoporosis
Menopause, with its associated estrogen deficiency, is the most important risk factor linked to increased bone turnover and bone loss.70 In addition, HIV is associated with bone loss, with low bone mineral density (BMD) described even among men and premenopausal women with HIV infection.71 Although decreased BMD associated with HIV stabilizes or even improves after initiation of ART in the younger population,72-74 chronic inflammation caused by HIV stimulates osteoclast differentiation and resorption.71 Other factors that appear to contribute to decreased BMD among PLWH include ART; vitamin D deficiency; low BMI; poor nutrition; inactivity; use of tobacco, alcohol, and illicit drugs; hepatitis B and C coinfection; and frailty, defined as increased vulnerability to stresses related to aging.72-80 Among ARTs, tenofovir disoproxil fumarate is associated with an increased risk of osteoporosis, and switching from this agent to tenofovir alafenamide improves bone density.81 Prolonged amenorrhea is also an added risk factor for osteoporosis in WLWH.82
Cognition
Both men and women living with HIV are at higher risk for cognitive impairment, ranging from minor cognitive-motor disorder to HIV-associated dementia.91 In addition, the menopause transition is characterized by cognitive changes, such as memory loss and difficulty concentrating.92,93 Studies focusing on the effects of both HIV infection and menopause on cognition have been limited thus far. A cross-sectional study demonstrated that HIV infection, but not menopausal stage, was associated with worse performance on cognitive measures.94 While menopausal stage was not associated with cognitive decline, menopausal symptoms like depression, anxiety, and vasomotor symptoms were associated with lower cognitive performance, highlighting the importance of recognition and treatment of menopausal symptoms.94
Test your knowledge of this topic HERE.
Cervical Dysplasia
WLWH are at increased risk for low- and high-grade squamous intraepithelial lesions (SILs) and more rapid progression to cervical carcinoma, as compared to women without HIV.95 This increased risk of cervical disease is associated with age, human papillomavirus genotype, and degree of immunosuppression.96 In addition, menopause appears to affect the risk of cervical disease. Postmenopausal WLWH had a higher risk of progression of SILs and persistence of lower-grade SILs compared to premenopausal women.97,98 Although studies on progression to cervical cancer in postmenopausal WLWH remain limited, current data suggest that postmenopausal WLWH should continue to be monitored and screened similarly to premenopausal women.
HIV Acquisition and Transmission
Women aged 50 years and older are primarily exposed to HIV through heterosexual contact.99 While the lack of awareness of HIV risk and less frequent use of barrier protection can contribute to new HIV infection in older women, physiologic changes associated with menopause also may be playing a role.100 Vaginal wall thinning and immunologic changes of the cervix that occur during menopause may serve as a risk factor for HIV acquisition. The cervicovaginal mucosa of postmenopausal women had higher levels of p24 antigen after ex vivo HIV-1 infection, suggesting higher susceptibility to acquire HIV infection.101 Postmenopausal women have been shown to have increased cervical CCR5 expression, which serves as an entry point of HIV into target cells.102 Finally, anti-HIV-1 activity was significantly decreased in postmenopausal women compared to premenopausal women.103 In addition, ex vivo studies demonstrated reduced tenofovir disoproxil fumarate and emtricitabine triphosphate concentrations in cervical tissue of postmenopausal women, suggesting that postmenopausal women may need higher doses of pre-exposure prophylaxis to achieve protective efficacy.104
HIV Progression
With prior data suggesting that younger persons experience better immunologic and virologic responses to ART,107-109 it had previously been hypothesized that virologic and immunologic responses to ART will decline once WLWH reach menopause. However, current studies suggest that menopause does not affect the progression of HIV and that ART-naive women should respond to ART, regardless of their menopausal status. Treatment responses to ART, determined by the median changes in CD4 cell counts and percentages and viral load, in ART-naive individuals did not differ between premenopausal and postmenopausal women.110 In addition, there appear to be no significant changes in CD4 cell counts as WLWH progress through menopause.111
Conclusion
As individuals with HIV infection live longer, an increasing number of women will enter menopause and live many years beyond menopause. WLWH experience earlier and more severe menopausal symptoms, but evidence on the appropriate management of these symptoms is still lacking. These conditions require proper surveillance, and can be prevented with an improved understanding of the effects of menopause on WLWH. However, there remain significant gaps in our understanding of menopause in WLWH. As practitioners encounter an increasing number of perimenopausal and postmenopausal WLWH, studies of the effects of HIV on comorbidities and symptoms of menopause and their appropriate management are necessary to improve care of WLWH.
Test your knowledge of this topic HERE.
More than half of the 37.9 million persons living with HIV (PLWH) worldwide are women.1 Between 2010 and 2016, 58% of women living with HIV (WLWH) in the United States were older than 45 years.2 As such, an increasing number of WLWH are entering menopause and living well beyond menopause. Despite this, health care providers expressed a lack of confidence in managing menopause in WLWH, and menopausal symptoms often are not recognized by providers.3 Enhancing our knowledge about menopause in WLWH is important, since the physiologic changes associated with menopause impact short- and long-term quality of life and mortality.
Test your knowledge of this topic HERE.
Amenorrhea
Menstrual irregularities, including amenorrhea and anovulation, are more frequently found in women of low socioeconomic status, presumably due to associated physical and emotional stress.4 In addition, women with low body mass index (BMI) have decreased serum estradiol levels, which lead to amenorrhea.4,5 Furthermore, low parity and many legal and illegal drugs are associated with amenorrhea, including hormonal contraceptives, opiates, stimulants, antipsychotics, and chemotherapeutic agents.6-8
Test your knowledge of this topic HERE.
Age at Menopause
In the United States, the median age of menopause is between 50 and 52 years in middle-class white women.11,12 Earlier menopause has been observed in women who are African American, are nulliparous, have a lower BMI, smoke tobacco, and have more stress, less education, and higher unemployment rates.11,13,14 Because 57% of women diagnosed with HIV in 2018 were African American and many WLWH have other risk factors associated with earlier menopause, studies examining the age of menopause in WLWH need to use a comparator group of women without HIV with similar characteristics and control for these factors to determine the influence of HIV on the age of menopause.
Menopause-Associated Symptoms
The perimenopausal period, which begins, on average, 4 years prior to the final menstrual period, is characterized by hormonal fluctuations leading to irregular menstrual cycles.19,20 Symptoms associated with these physiologic changes during the perimenopausal period include vasomotor symptoms (hot flashes), genitourinary symptoms (vaginal dryness and dyspareunia), anxiety, depression, sleep disturbances, and joint aches.21,22 Such menopausal symptoms can be distressing and negatively impact quality of life.23 In WLWH, severe menopausal symptoms have been associated with suboptimal adherence to antiretroviral therapy (ART).24
Vasomotor
In the United States, the most common symptom during perimenopause is hot flashes, which occur in 38% to 80% of women.32,33 Vasomotor symptoms are most common in women who smoke, use illicit substances, have a high BMI, are of lower socioeconomic status, and are African American.11 As expected, prior studies focusing on hot flash prevalence among premenopausal, perimenopausal, and postmenopausal WLWH found that postmenopausal women experience more hot flashes than premenopausal or perimenopausal women.27,28 In addition, a comparison of women with and without HIV demonstrated a higher prevalence of hot flashes among WLWH.26,29 Vasomotor symptoms can be severely distressing, with hot flashes contributing to increased risk of depression.25,34 In a cross-sectional analysis of 835 WLWH and 335 women without HIV from the WIHS cohort, persistent vasomotor symptoms predicted elevated depressive symptoms in both WLWH and women without HIV.34 In a similar cross-sectional analysis of 536 women, among whom 54% were WLWH and 37% were perimenopausal, psychological symptoms were prevalent in 61% of the women with vasomotor symptoms.29
Genitourinary
Estrogen deficiency, which accompanies the perimenopausal period, leads to vulvovaginal atrophy (VVA), manifesting with symptoms of vaginal dryness, itching, burning, urinary urgency, and dyspareunia (painful intercourse).33,35,36 Unlike vasomotor symptoms, which diminish with time, genitourinary symptoms generally worsen if left untreated.37 Furthermore, these symptoms are often underreported and underdiagnosed.38,39 VVA was found in 43% to 84% of postmenopausal women.36,40,41 In the AGATA study, the prevalence of VVA was associated with years since menopause. 36 Vaginal dryness and dyspareunia were common.
Psychiatric
Anxiety and depression are also common symptoms in perimenopausal women.46-48 Studies have shown that depression is diagnosed 2.5 times more frequently among perimenopausal women than premenopausal women.48 In a study by Miller et al that focused on 536 WLWH, among whom 37% were perimenopausal, 89% reported psychological symptoms.29 Ferreira et al found that perimenopausal WLWH had an increased incidence of psychological symptoms, such as depression and anxiety, compared to women without HIV infection.26 Whether this increased prevalence of psychological symptoms seen in WLWH can be attributed to menopause is unclear, since one third to one half of men and women living with HIV experience symptoms of depression.49 However, in the WIHS, which compared findings from 835 WLWH to findings from 335 women without HIV from all menopausal stages, elevated depressive symptoms were seen in the early perimenopausal period.34 There was no increased incidence of such symptoms during the premenopausal or postmenopausal stage, suggesting that factors related to menopause contribute to depressive symptoms during the perimenopausal stage.34
Other Symptoms
Sleep disturbances are common among perimenopausal women, with an estimated prevalence between 38% and 46%.52-54 Hot flashes, anxiety, and depression appear to be factors that contribute to sleep difficulty.52-54 In a cross-sectional study of 273 WLWH and 264 women without HIV between 40 and 60 years of age, insomnia was found in 51% of perimenopausal and 53% of postmenopausal WLWH. The prevalence of insomnia in WLWH and women without HIV was the same.55 Joint aches are also commonly reported in the perimenopausal period, with a prevalence as high as 50% to 60% among perimenopausal women in the United States.22,29 Miller and colleagues found that 63% of menopausal WLWH reported arthralgia.29
Test your knowledge of this topic HERE.
Treatment
Despite the increased severity of menopausal symptoms experienced among WLWH, menopausal replacement therapy (MRT) is used less frequently in WLWH than in women living without HIV.55 Topical treatment is recommended for women who are experiencing vaginal dryness. First-line treatment is topical nonhormonal therapy, such as moisturizers and lubricants.56 If symptoms are not relieved, then topical vaginal estrogen therapy is recommended.56 Randomized placebo-controlled studies have verified the safety and efficacy of topical estrogen in the general population, and there is no reason to expect different outcomes in WLWH.57,58
Cardiovascular Risk
Estrogen deficiency that occurs during menopause leads to an increased risk of cardiovascular disease, particularly with changes in lipid profiles, insulin resistance, and body composition (eg, increased fat mass and waist circumference).61 HIV infection also is associated with a higher risk of cardiovascular disease, with studies consistently reporting a 1.5- to 2-fold increase in the rate of cardiovascular events in PLWH compared to persons without HIV.62 The inflammatory effects of HIV as well as ART exposure, specifically to PIs and abacavir, increase the risk for cardiovascular disease.62 In addition, traditional risk factors, including dyslipidemia, contribute to cardiovascular disease risk in this population.63,64
Osteoporosis
Menopause, with its associated estrogen deficiency, is the most important risk factor linked to increased bone turnover and bone loss.70 In addition, HIV is associated with bone loss, with low bone mineral density (BMD) described even among men and premenopausal women with HIV infection.71 Although decreased BMD associated with HIV stabilizes or even improves after initiation of ART in the younger population,72-74 chronic inflammation caused by HIV stimulates osteoclast differentiation and resorption.71 Other factors that appear to contribute to decreased BMD among PLWH include ART; vitamin D deficiency; low BMI; poor nutrition; inactivity; use of tobacco, alcohol, and illicit drugs; hepatitis B and C coinfection; and frailty, defined as increased vulnerability to stresses related to aging.72-80 Among ARTs, tenofovir disoproxil fumarate is associated with an increased risk of osteoporosis, and switching from this agent to tenofovir alafenamide improves bone density.81 Prolonged amenorrhea is also an added risk factor for osteoporosis in WLWH.82
Cognition
Both men and women living with HIV are at higher risk for cognitive impairment, ranging from minor cognitive-motor disorder to HIV-associated dementia.91 In addition, the menopause transition is characterized by cognitive changes, such as memory loss and difficulty concentrating.92,93 Studies focusing on the effects of both HIV infection and menopause on cognition have been limited thus far. A cross-sectional study demonstrated that HIV infection, but not menopausal stage, was associated with worse performance on cognitive measures.94 While menopausal stage was not associated with cognitive decline, menopausal symptoms like depression, anxiety, and vasomotor symptoms were associated with lower cognitive performance, highlighting the importance of recognition and treatment of menopausal symptoms.94
Test your knowledge of this topic HERE.
Cervical Dysplasia
WLWH are at increased risk for low- and high-grade squamous intraepithelial lesions (SILs) and more rapid progression to cervical carcinoma, as compared to women without HIV.95 This increased risk of cervical disease is associated with age, human papillomavirus genotype, and degree of immunosuppression.96 In addition, menopause appears to affect the risk of cervical disease. Postmenopausal WLWH had a higher risk of progression of SILs and persistence of lower-grade SILs compared to premenopausal women.97,98 Although studies on progression to cervical cancer in postmenopausal WLWH remain limited, current data suggest that postmenopausal WLWH should continue to be monitored and screened similarly to premenopausal women.
HIV Acquisition and Transmission
Women aged 50 years and older are primarily exposed to HIV through heterosexual contact.99 While the lack of awareness of HIV risk and less frequent use of barrier protection can contribute to new HIV infection in older women, physiologic changes associated with menopause also may be playing a role.100 Vaginal wall thinning and immunologic changes of the cervix that occur during menopause may serve as a risk factor for HIV acquisition. The cervicovaginal mucosa of postmenopausal women had higher levels of p24 antigen after ex vivo HIV-1 infection, suggesting higher susceptibility to acquire HIV infection.101 Postmenopausal women have been shown to have increased cervical CCR5 expression, which serves as an entry point of HIV into target cells.102 Finally, anti-HIV-1 activity was significantly decreased in postmenopausal women compared to premenopausal women.103 In addition, ex vivo studies demonstrated reduced tenofovir disoproxil fumarate and emtricitabine triphosphate concentrations in cervical tissue of postmenopausal women, suggesting that postmenopausal women may need higher doses of pre-exposure prophylaxis to achieve protective efficacy.104
HIV Progression
With prior data suggesting that younger persons experience better immunologic and virologic responses to ART,107-109 it had previously been hypothesized that virologic and immunologic responses to ART will decline once WLWH reach menopause. However, current studies suggest that menopause does not affect the progression of HIV and that ART-naive women should respond to ART, regardless of their menopausal status. Treatment responses to ART, determined by the median changes in CD4 cell counts and percentages and viral load, in ART-naive individuals did not differ between premenopausal and postmenopausal women.110 In addition, there appear to be no significant changes in CD4 cell counts as WLWH progress through menopause.111
Conclusion
As individuals with HIV infection live longer, an increasing number of women will enter menopause and live many years beyond menopause. WLWH experience earlier and more severe menopausal symptoms, but evidence on the appropriate management of these symptoms is still lacking. These conditions require proper surveillance, and can be prevented with an improved understanding of the effects of menopause on WLWH. However, there remain significant gaps in our understanding of menopause in WLWH. As practitioners encounter an increasing number of perimenopausal and postmenopausal WLWH, studies of the effects of HIV on comorbidities and symptoms of menopause and their appropriate management are necessary to improve care of WLWH.
Test your knowledge of this topic HERE.
1. UNAIDS. AIDSInfo. 2019 estimates https://www.unaids.org/en/resources/infographics/girls-and-women-living-with-HIV. Accessed April 30, 2020.
2. Centers for Disease Control and Prevention. Estimated HIV incidence and prevalence in the United States, 2010–2016. HIV Surveillance Supplemental Report 2019;24(No. 1). www.cdc.gov/hiv/library/reports/hiv-surveillance.html. Accessed April 30, 2020.
3. Chirwa M, Ma R, Guallar C, et al. Managing menopause in women living with HIV: A survey of primary care practitioners. Post Reprod Health. 2017;23:111-115.
4. Munster K, Helm P, Schmidt L. Secondary amenorrhea: Prevalence and medical contract–A cross sectional study from a Danish county. Br J Obstet Gynecol. 1992;99:430-433.
5. Vyver E, Steinegger C, Katzman DK, et al. Eating disorders and menstrual dysfunction in adolescents. Ann N Y Acad Sci. 2008;1135: 253-264.
6. Cejtin HE, Evans CT, Greenblatt R, et al. Prolonged amenorrhea and resumption of menses in women with HIV. J Womens Health (Larchmt). 2018;27:1441‐1448.
7. Bai J, Greenwald E, Caterini H, et al. Drug-related menstrual aberrations. Obstet Gynecol. 1974;44:713-719.
8. Cejtin HE, Kalinowski A, Bacchetti P. Effects of human immunodeficiency virus on protracted amenorrhea and ovarian dysfunction. Obstet Gynecol. 2006;108:1423-1431.
9. King EM, Albert AY, Murray MCM. HIV and amenorrhea: a meta-analysis. AIDS. 2019;33:483‐491.
10. Watts DH, Spino C, Zaborski L. Comparison of gynecologic history and laboratory results in HIV-positive women with CDR+ lymphocyte counts between 200 and 500 cells/μl and below 100 cells/ μl. J Acquir Immune Defic Syndr Hum Retrovirol. 1999;20:455-462.
11. Gold EB, Crawford SL, Avis NE, et al. Factors related to age at natural menopause: longitudinal analyses from SWAN. Am J Epidemiol. 2013;178:70-83.
12. Thomas F, Renaud F, Benefice E, et al. International variability of ages at menarche and menopause: patterns and main determinants. Hum Biol. 2001;73:271-290.
13. Bromberger JT, Matthews KA, Kuller LH, et al. Prospective study of the determinants of age at menopause. Am J Epidemiol. 1997; 145:24-33.
14. Schoenbaum E, Hartel D, Lo Y, et al. HIV infection, drug use, and onset of natural menopause. Clinical Infect Dis. 2005;41: 1517-1524.
15. Research on the menopause in the 1990s. Report of a WHO scientific group. World Health Organ Tech Rep Ser. 1996;866:1-107.
16. de Pommerol M, Hessamfar M, Lawson-Ayayi S, et al. Menopause and HIV infection: age at onset and associated factors, ANRS CO3 Aquitaine cohort. Int J STD AIDS. 2011;22:67-72.
17. Calvet G, Grinsztejn G. Predictors of early menopause in HIV infected women: a prospective cohort study. Am J Obstet Gynecol. 2015;212:765.
18. Cejtin SH, Taylor R, Watts DH. Assessment of menopausal status among women in the Women’s Interagency HIV study (WIHS). Proceedings of the XV International AIDS Conference; July 11-16, 2004; Bangkok, Thailand.
19. Taffe JR, Dennerstein L. Menstrual patterns leading to the final menstrual period. Menopause. 2002;9:32-40.
20. Miro F, Parker SW, Aspinall LJ, et al. Origins and consequences of the elongation of the human menstrual cycle during the menopausal transition: the FREEDOM Study. J Clin Endocrinol Metab. 2004;89:4910-4915.
21. McKinlay SM, Brambilla DJ, Posner JG. The normal menopause transition. Maturitas. 1992;14:103-115.
22. Blümel JE, Chedraui P, Baron G, et al. Menopause could be involved in the pathogenesis of muscle and joint aches in mid-aged women. Maturitas. 2013;75:94-100.
23. Woods NF, Mitchell ES. Symptoms interference with work and relationships during the menopausal transition and early postmenopause: observations from the Seattle Midlife Women’s Health Study. Menopause. 2011;18:654-661.
24. Duff PK, Money DM, Ogilvie GS, et al. Severe menopausal symptoms associated with reduced adherence to antiretroviral therapy among perimenopausal and menopausal women living with HIV in Metro Vancouver. Menopause. 2018;25:531-537.
25. Johnson TM, Cohen HW, Howard AA, et al. Attribution of menopause symptoms in human immunodeficiency virus–infected or at-risk drug-using women. Menopause. 2008;15:551-557.
26. Ferreira CE, Pinto-Neto AM, Conde DM, et al. Menopausal symptoms in women infected with HIV: prevalence and associated factors. Gynecol Endocrinol. 2007;23:198-205.
27. Fantry L, Zhan M, Taylor G, et al. Age at menopause and menopausal symptoms in HIV-infected women. AIDS Patient Care STD. 2005;19:703-711.
28. Boonyanurak P, Bunupuradah T, Wilawan K, et al. Age at menopause and menopause-related symptoms in human immunodeficiency virus-infected Thai women. Menopause. 2012;19: 820-824.
29. Miller SA, Santoro N, Lo Y. Menopausal symptoms in HIV-infected and drug-using women. Menopause. 2005;12:348-356.
30. Looby S, Shifren J, Corless I. Increased hot flash severity and related interference in perimenopausal HIV-infected women. Menopause. 2014;21:403-409.
31. Schnall R, Jia H, Olender S, et al. In people living with HIV (PLWH), menopause (natural or surgical) contributes to the greater symptom burden in women: results from an online US survey. Menopause. 2018;25:744-752.
32. Thurston RC, Joffe H. Vasomotor symptoms and menopause: findings from the Study of Women’s Health across the Nation. Obstet Gynecol Clin North Am. 2011;38:489-501.
33. Woods NF, Mitchell ES. Symptoms during the perimenopause: prevalence, severity, trajectory, and significance in women’s lives. Am J Med. 2005;118 Suppl 12B:14-24.
34. Maki PM, Rubin LH, Cohen M, et al. Depressive symptoms are increased in the early perimenopausal stage in ethnically diverse human immunodeficiency virus-infected and human immunodeficiency virus-uninfected women. Menopause. 2012;19: 1215-1233.
35. Dennerstein L, Dudley EC, Hopper JL, et al. A prospective population-based study of menopausal symptoms. Obstet Gynecol. 2000;96:351-358.
36. Palma F, Volpe A, Villa P, et al. Vaginal atrophy of women in postmenopause. Results from a multicentric observational study: The AGATA study. Maturitas. 2016;83:40-44.
37. Cutler WB, Garcia CR, McCoy N. Perimenopausal sexuality. Arch Sex Behav. 1987;16:225-234.
38. Moreira ED, Glasser DB, Nicolosi A, et al. GSSAB Investigators’ Group. Sexual problems and help-seeking behavior in adults in the United Kingdom and continental Europe. BJU Int. 2008;101:1005-1111.
39. MacBride MB, Rhodes DJ, Shuster LT. Vulvovaginal atrophy. Mayo Clin Proc. 2010;85:87-94.
40. Nappi RE, Kokot-Kierepa M. Women’s voices in the menopause: results from an international survey on vaginal atrophy. Maturitas. 2010;67:233-238.
41. Santoro N, Komi J. Prevalence and impact of vaginal symptoms among postmenopausal women. J Sex Med. 2009;6:2133-2142.
42. Valadares AL, Pinto-Neto AM, Conde DM, et al. A population-based study of dyspareunia in a cohort of middle-aged Brazilian women. Menopause. 2008;15:1184-1190.
43. Latthe P, Migini L, Gray R, et al. Factors predisposing women to chronic pelvic pain: a systemic review. BMJ. 2006;332:749-755.
44. Potter DA, Moreno A, Luther MF, et al. Effects of follicular-phase cocaine administration on menstrual and ovarian cyclicity in rhesus monkeys. Am J Obstet Gynecol. 1998;178:118-125.
45. Valadares AL, Pinto-Neto AM, Gomes D, et al. Dyspareunia in HIV-positive and HIV-negative middle-aged women: a cross-sectional study. BMJ Open. 2014;4:e004974.
46. Bromberger JT, Meyer PM, Kravitz HM, et al. Psychologic distress and natural menopause: a multiethnic community study. Am J Public Health. 2001;91:1435-1442.
47. Avis NE, Brambilla D, McKinlay SM, Vass K. A longitudinal analysis of the association between menopause and depression. Results from the Massachusetts Women’s Health Study. Ann Epidemiol. 1994;4:214-220.
48. Freeman EW, Sammel MD, Lin H, Nelson DB. Associations of hormones and menopausal status with depressed mood in women with no history of depression. Arch Gen Psychiatry. 2006; 63:375-382.
49. Eller LS, Corless I, Bunch EH, et al. Self-care strategies for depressive symptoms in people with HIV disease. J Adv Nurs. 2005;51:119-130.
50. Fuh JL, Wang SJ, Lee SJ, et al. A longitudinal study of cognition change during early menopausal transition in a rural community. Maturitas. 2006;53:447-453.
51. Hinkin CH, Castellon SA, Atkinson JH, et al. Neuropsychiatric aspects of HIV infection among older adults. J Clin Epidemiol. 2001;54:S44-S52
52. Kravitz HM, Ganz PA, Bromberger J, et al. Sleep difficulty in women at midlife: a community survey of sleep and the menopausal transition. Menopause. 2003;10:19-28.
53. Freedman RR, Roehrs TA. Effects of REM sleep and ambient temperature on hot flash-induced sleep disturbance. Menopause. 2006;13:576-583.
54. Erlik Y, Tataryn IV, Meldrum DR, et al. Association of waking episodes aspects of HIV infection among older adults. J Clin Epidemiol. 2001;54:S44–52.
55. Lui-Filho JF, Valadares AR, Gomes D, et al. Menopausal symptoms and associated factors in HIV-positive women. Maturitas. 2013;76:172-178.
56. Management of symptomatic vulvovaginal atrophy: 2013 position statement of The North American Menopause Society. Menopause. 2013;20:888‐904.
57. Fernandes T, Pedro AO, Baccaro LF, et al. Hormonal, metabolic, and endometrial safety of testosterone vaginal cream versus estrogens for the treatment of vulvovaginal atrophy in postmenopausal women: a randomized, placebo-controlled study. Menopause. 2018; 25:641‐647.
58. Kroll R, Archer DF, Lin Y, et al. A randomized, multicenter, double-blind study to evaluate the safety and efficacy of estradiol vaginal cream 0.003% in postmenopausal women with dyspareunia as the most bothersome symptom. Menopause. 2018;25:133‐138.
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60. Tittle, V, Bull, L, Boffito, M. Pharmacokinetic and pharmacodynamics drug interactions between antiretrovirals and oral contraceptives. Clin Pharmacokinet. 2015;54:23-34.
61. Sower M, Zheng H, Tomey K, et al. Changes in body composition in women over six years at midlife: ovarian and chronological aging. J Clin Endocrin Metab. 2007;92:895- 901.
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63. Flooris-Moore M, Howard AA, Lo Y, et al. Increased serum lipids are associated with higher CD4 lymphocyte count in HIV-infected women. HIV Med. 2006;7:421-430.
64. Hadigan C, Meigs JB, Corcoran C, et al. Metabolic abnormalities and cardiovascular disease risk factors in adults with human immunodeficiency virus infection and lipodystrophy. Clin Infect Dis. 2001;32:130-139.
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70. Akhter MP, Lappe JM, Davies KM, et al. Transmenopausal changes in the trabecular bone structure. Bone. 2007;41:111-116.
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34. Maki PM, Rubin LH, Cohen M, et al. Depressive symptoms are increased in the early perimenopausal stage in ethnically diverse human immunodeficiency virus-infected and human immunodeficiency virus-uninfected women. Menopause. 2012;19: 1215-1233.
35. Dennerstein L, Dudley EC, Hopper JL, et al. A prospective population-based study of menopausal symptoms. Obstet Gynecol. 2000;96:351-358.
36. Palma F, Volpe A, Villa P, et al. Vaginal atrophy of women in postmenopause. Results from a multicentric observational study: The AGATA study. Maturitas. 2016;83:40-44.
37. Cutler WB, Garcia CR, McCoy N. Perimenopausal sexuality. Arch Sex Behav. 1987;16:225-234.
38. Moreira ED, Glasser DB, Nicolosi A, et al. GSSAB Investigators’ Group. Sexual problems and help-seeking behavior in adults in the United Kingdom and continental Europe. BJU Int. 2008;101:1005-1111.
39. MacBride MB, Rhodes DJ, Shuster LT. Vulvovaginal atrophy. Mayo Clin Proc. 2010;85:87-94.
40. Nappi RE, Kokot-Kierepa M. Women’s voices in the menopause: results from an international survey on vaginal atrophy. Maturitas. 2010;67:233-238.
41. Santoro N, Komi J. Prevalence and impact of vaginal symptoms among postmenopausal women. J Sex Med. 2009;6:2133-2142.
42. Valadares AL, Pinto-Neto AM, Conde DM, et al. A population-based study of dyspareunia in a cohort of middle-aged Brazilian women. Menopause. 2008;15:1184-1190.
43. Latthe P, Migini L, Gray R, et al. Factors predisposing women to chronic pelvic pain: a systemic review. BMJ. 2006;332:749-755.
44. Potter DA, Moreno A, Luther MF, et al. Effects of follicular-phase cocaine administration on menstrual and ovarian cyclicity in rhesus monkeys. Am J Obstet Gynecol. 1998;178:118-125.
45. Valadares AL, Pinto-Neto AM, Gomes D, et al. Dyspareunia in HIV-positive and HIV-negative middle-aged women: a cross-sectional study. BMJ Open. 2014;4:e004974.
46. Bromberger JT, Meyer PM, Kravitz HM, et al. Psychologic distress and natural menopause: a multiethnic community study. Am J Public Health. 2001;91:1435-1442.
47. Avis NE, Brambilla D, McKinlay SM, Vass K. A longitudinal analysis of the association between menopause and depression. Results from the Massachusetts Women’s Health Study. Ann Epidemiol. 1994;4:214-220.
48. Freeman EW, Sammel MD, Lin H, Nelson DB. Associations of hormones and menopausal status with depressed mood in women with no history of depression. Arch Gen Psychiatry. 2006; 63:375-382.
49. Eller LS, Corless I, Bunch EH, et al. Self-care strategies for depressive symptoms in people with HIV disease. J Adv Nurs. 2005;51:119-130.
50. Fuh JL, Wang SJ, Lee SJ, et al. A longitudinal study of cognition change during early menopausal transition in a rural community. Maturitas. 2006;53:447-453.
51. Hinkin CH, Castellon SA, Atkinson JH, et al. Neuropsychiatric aspects of HIV infection among older adults. J Clin Epidemiol. 2001;54:S44-S52
52. Kravitz HM, Ganz PA, Bromberger J, et al. Sleep difficulty in women at midlife: a community survey of sleep and the menopausal transition. Menopause. 2003;10:19-28.
53. Freedman RR, Roehrs TA. Effects of REM sleep and ambient temperature on hot flash-induced sleep disturbance. Menopause. 2006;13:576-583.
54. Erlik Y, Tataryn IV, Meldrum DR, et al. Association of waking episodes aspects of HIV infection among older adults. J Clin Epidemiol. 2001;54:S44–52.
55. Lui-Filho JF, Valadares AR, Gomes D, et al. Menopausal symptoms and associated factors in HIV-positive women. Maturitas. 2013;76:172-178.
56. Management of symptomatic vulvovaginal atrophy: 2013 position statement of The North American Menopause Society. Menopause. 2013;20:888‐904.
57. Fernandes T, Pedro AO, Baccaro LF, et al. Hormonal, metabolic, and endometrial safety of testosterone vaginal cream versus estrogens for the treatment of vulvovaginal atrophy in postmenopausal women: a randomized, placebo-controlled study. Menopause. 2018; 25:641‐647.
58. Kroll R, Archer DF, Lin Y, et al. A randomized, multicenter, double-blind study to evaluate the safety and efficacy of estradiol vaginal cream 0.003% in postmenopausal women with dyspareunia as the most bothersome symptom. Menopause. 2018;25:133‐138.
59. Panel on Antiretroviral Guidelines for Adults and Adolescents. Guidelines for the use of antiretroviral agents in adults and adolescents with HIV. Department of Health and Human Services. Tables 21a-d.www.aidsinfo.nih.gov/ContentFiles/ AdultandAdolescentGL.pdf. Accessed May 4, 2020.
60. Tittle, V, Bull, L, Boffito, M. Pharmacokinetic and pharmacodynamics drug interactions between antiretrovirals and oral contraceptives. Clin Pharmacokinet. 2015;54:23-34.
61. Sower M, Zheng H, Tomey K, et al. Changes in body composition in women over six years at midlife: ovarian and chronological aging. J Clin Endocrin Metab. 2007;92:895- 901.
62. Eyawo O, Brockman G, Goldsmith CH, et al. Risk of myocardial infarction among people living with HIV: an updated systematic review and meta-analysis. BMJ Open. 2019;9:e025874.
63. Flooris-Moore M, Howard AA, Lo Y, et al. Increased serum lipids are associated with higher CD4 lymphocyte count in HIV-infected women. HIV Med. 2006;7:421-430.
64. Hadigan C, Meigs JB, Corcoran C, et al. Metabolic abnormalities and cardiovascular disease risk factors in adults with human immunodeficiency virus infection and lipodystrophy. Clin Infect Dis. 2001;32:130-139.
65. Grinspoon S, Carr A. Cardiovascular risk and body fat abnormalities in HIV-infected adults. N Engl J Med. 2005; 352:48–62.
66. Study of Fat Redistribution and Metabolic Change in HIV Infection (FRAM). Fat distribution in women with HIV infection. J Acquir Immune Defic Syndr. 2006;42:562-571.
67. Alcaide ML, Parmigiani A, Pallikkuth S, et al. Immune activation in HIV-infected aging women on antiretrovirals--implications for age-associated comorbidities: a cross-sectional pilot study. PLoS One. 2013;8:e63804.
68. Karim R, Mack WJ, Kono N, et al. Gonadotropin and sex steroid levels in HIV-infected premenopausal women and their association with subclinical atherosclerosis in HIV-infected and -uninfected women in the women’s interagency HIV study (WIHS). J Clin Endocrinol Metab. 2013;98:E610‐E618.
69. Looby SE, Fitch KV, Srinivasa S, et al. Reduced ovarian reserve relates to monocyte activation and subclinical coronary atherosclerotic plaque in women with HIV. AIDS. 2016;30:383‐393.
70. Akhter MP, Lappe JM, Davies KM, et al. Transmenopausal changes in the trabecular bone structure. Bone. 2007;41:111-116.
71. Gibellini D, De Crignis E, Ponti C. HIV-1 triggers apoptosis in primary osteoblasts and HOBIT cells through TNF-alpha activation. J Med Virol. 2008;80:1507-1514.
72. Cassetti I, Madruga JV, Suleiman JM, et al. The safety and efficacy of tenofovir DF in combination with lamivudine and efavirenz through 6 years in antiretroviral-naive HIV- 1-infected patients. HIV Clin Trials. 2007;8:164-172.
73. McComsey GA, Kitch D, Daar ES, et al. Bone mineral density and fractures in antiretroviral-naive persons randomized to receive abacavir-lamivudine or tenofovir disoproxil fumarate-emtricitabine along with efavirenz or atazanavir-ritonavir: AIDS Clinical Trials Group A5224s, a substudy of ACTG A5202. J Infect Dis. 2011;203: 1791-1801.
74. Hansen AB, Obel N, Nielsen H, et al. Bone mineral density changes in protease inhibitor-sparing vs. nucleoside reverse transcriptase inhibitor-sparing highly active antiretroviral therapy: Data from a randomized trial. HIV Med. 2011;12:157-165.
75. FDao CN, Patel P, Overton ET, et al. Study to understand the natural history of HIV and AIDS in the era of effective therapy (SUN) investigators. Low vitamin D among HIV-infected adults: prevalence of and risk factors for low vitamin D levels in cohort of HIV-infected adults and comparison to prevalence among adults in the US general population. Clin Infect Dis. 2011;52:396-405.
76. Jacobson DL, Spiegelman D, Know TK, Wilson IB. Evolution and predictors of change in total bone mineral density over time in HIV-infected men and women in the nutrition for healthy living study. J Acquir Immune Defic Syndr Hum Retrovirol. 2008;49:298-308.
77. Kanis JA, Borgstrom F, De Laet C, et al. Assessment of fracture risk. Osteoporosis Int. 2005;16:581-589.
78. Pedrazzoni M, Vescovi L, Maninetti M, et al. Effects of chronic heroine abuse on bone and mineral metabolism. Acta Endocrinol. 1993;129:42-45.
79. Lo Re V 3rd, Guaraldi G, Leonard MB, et al. Viral hepatitis is associated with reduced bone mineral density in HIV-infected women but not men. AIDS. 1990;23:2191-2198.
80. Bregigeon S, Galinier A, Zaegel-Faucher O, et al. Frailty in HIV infected people: a new risk factor for bone mineral density loss [published correction appears in AIDS. AIDS. 2017;31: 1573‐1577.
81. Mills A, Arribas JR, Andrade-Villanueva J, et al. Switching from tenofovir disoproxil fumarate to tenofovir alafenamide in antiretroviral regimens for virologically suppressed adults with HIV-1 infection: a randomised, active-controlled, multicentre, open-label, phase 3, non-inferiority study. Lancet Infect Dis. 2015;16:43-45.
82. King EM, Nesbitt A, Albert AYK, et al. Prolonged amenorrhea and low hip bone mineral density in women living with HIV-a controlled cross-sectional study. J Acquir Immune Defic Syndr. 2020;83:
486‐495.
83. Yin MT, Mcmahon DJ, Ferris DC, et al. Low bone mass and high bone turnover in postmenopausal human immunodeficiency virus-infected women. J Clin Endocrinol Metab. 2010;95:620-629.
84. Yin MT, Modarresi R, Shane E, et al. Effects of HIV infection and antiretroviral therapy with ritonavir on induction of osteoclast-like cells in postmenopausal women. Osteoporos Int. 2011;22:1459-1466.
85. Sharma A, Cohen HW, Freeman R, et al. Prospective evaluation of bone mineral density among middle-aged HIV-infected and uninfected women: association between methadone use and bone loss. Maturitas. 2011;70:295-301.
86. Sharma A, Flom PL, Rosen CJ, et al. Racial differences in bone loss and relation to menopause among HIV-infected and uninfected women. Bone. 2015;77:24-30.
87. Aberg JA, Gallant JE, Ghanem KG, et al, Infectious Diseases Society of America. Primary care guidelines for the management of persons infected with HIV: 2013 update by the HIV medicine association of the Infectious Diseases Society of America. Clin Infect Dis. 2014;58:1‐10.
88. National Osteoporosis Foundation. Clinician’s guide to prevention and treatment of osteoporosis 2014. Washington, DC: National Osteoporosis Foundation; 2014.
89. Yin MT, Choudhury A, Bucovsky M, et al. A randomized placebo-controlled trial of low- versus moderate-dose vitamin d3 supplementation on bone mineral density in postmenopausal women with HIV. J Acquir Immune Defic Syndr. 2019;80:342-349.
90. McComsey GA, Tebas P, Shane E, et al. Bone disease in HIV infection: a practical review and recommendations for HIV care providers. Clin Infect Dis. 2010;51:937-946.
91. Price RW. Neurological complications of HIV infection. Lancet. 1996;348:445-452.
92. Soares CN, Maki PM. Menopausal transition, mood, and cognition: an integrated view to close the gaps. Menopause. 2010;17:812-814.
93. Greendale GA, Wight RG, Huang MH, et al. Menopause-associated symptoms and cognitive performance: results from the study of women’s health across the nation. Am J Epidemiol. 2010;171:1214-1224.
94. Rubin LH, Sundermann EE, Cook JA, et al. An investigation of menopausal stage and symptoms on cognition in HIV-infected women. Menopause. 2014;21:997-1006.
95. Ellerbrock TV, Chiasson MA, Bush TJ, et al. Incidence of cervical squamous intraepithelial lesions in HIV-infected women. JAMA. 2000;283:1031-1037.
96. Mandelblatt JS, Kanetsky P, Eggert L, et al. Is HIV infection a cofactor for cervical squamous cell neoplasia? Cancer Epidemiol Biomarkers Prev. 1999;8:97-106.
97. Kim SC, Messing S, Shah K, et al. Effects of highly active antiretroviral therapy (HAART) and menopause on risk of progression of cervical dysplasia in human immune deficiency virus (HIV) infected women. Infect Dis Obstet Gynecol. 2013;2013:784718.
98. Ceccaldi PF, Ferreira C, Coussy F, et al. Cervical disease in postmenopausal HIV-1 infected women. J Gynecol Obstet Biol Reprod. 2010;39:466-470.
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100. Levy JA, Ory MG, Crystal S. HIV/AIDS interventions for midlife and older adults: current status and challenges. J Acquir Immune Defic Syndr. 2003;33 Suppl 2:S59-S67.
101. Thurman AR, Yousefieh N, Chandra N, et al. Comparison of mucosal markers of human immunodeficiency virus susceptibility in healthy premenopausal versus postmenopausal women. AIDS Res Hum Retroviruses. 2017;33:807-819.
102. Meditz AL, Moreau KL, MaWhinney S, et al. CCR5 expression is elevated on endocervical CD4+ T cells in healthy postmenopausal women. J Acquir Immune Defic Syndr. 2012;59:221-228.
103. Chappell CA, Isaacs CE, Xu W, et al. The effect of menopause on the innate antiviral activity of cervicovaginal lavage. Am J Obstet Gynecol. 2015;213:204.
104. Nicol MR, Brewers LM, Kashuba ADM, et al. The role of menopause in tenofovir diphosphate and emtricitabine triphosphate concentrations in cervical tissue. AIDS. 2018;32:11-15.
105. Melo KC, Melo MR, Ricci BV, Segurado AC. Correlates of human immunodeficiency virus cervicovaginal shedding among postmenopausal and fertile-aged women. Menopause. 2012;19:150-156.
106. Landolt NK, Do T, Kasipong N, et al. Low-level genital HIV shedding in Thai HIV-infected women with suppressed plasma viral load after menopause: a longitudinal study. J Virus Erad. 2017;3:204-207.
107. Viard JP, Mocroft A, Chiesi A, et al. Influence of age of CD4 cell recovery in human immunodeficiency virus-infected patients receiving highly active antiretroviral therapy: evidence from the Euro SIDA study. J Infect Dis. 2001;193:1290-1294.
108. Grabar S, Kousignian I, Sobel A, et al. Immunological and clinical responses to highly active antiretroviral therapy over 50 years of age. Results from the French Hospital Database on HIV. AIDS. 2004;18:2029-2038.
109. Cuzin L, Delpierre C, Gerard S, et al. Immunologic and clinical responses to highly active antiretroviral therapy in patients with HIV infection aged >50 years. Clin Infect Dis. 2007;45:654-657.
110. Patterson KB, Cohn SE, Uynik J, et al. Treatment responses in antiretroviral treatment-naïve premenopausal and postmenopausal HIV-1 infected women: an analysis from AIDS clinical trials group studies. Clin Infect Dis. 2009;49:473476.
111. van Benthem BH, Vernazza P, Coutinho RA, et al. The impact of pregnancy and menopause on CD4 lymphocyte count in HIV-infected women. AIDS. 2002;16:919-922.
Rolled into one? Weeding out evidence on cognitive impact of marijuana from that of THC
This supplement to Neurology Reviews summarizes summarize findings from English-only, peer-reviewed original articles and meta-analyses of specified cannabinoids’ effect on cognition in preclinical and clinical literature, where known, to guide practitioners with proper evidence and highlighting gaps in knowledge for future research.
Click here to read the supplement.
Authors
Francesca Filbey, PhD
Bert Moore Chair and Professor
of Cognition and Neuroscience
The University of Texas at Dallas
Chris Hauser, PhD
Medical Science Liaison
Greenwich Biosciences, Inc.
Karthik Rajasekaran, PhD
Sr. Medical Science Liaison
Greenwich Biosciences, Inc.
1. Mead A. Front Plant Sci. 2019;10:697.
This supplement to Neurology Reviews summarizes summarize findings from English-only, peer-reviewed original articles and meta-analyses of specified cannabinoids’ effect on cognition in preclinical and clinical literature, where known, to guide practitioners with proper evidence and highlighting gaps in knowledge for future research.
Click here to read the supplement.
Authors
Francesca Filbey, PhD
Bert Moore Chair and Professor
of Cognition and Neuroscience
The University of Texas at Dallas
Chris Hauser, PhD
Medical Science Liaison
Greenwich Biosciences, Inc.
Karthik Rajasekaran, PhD
Sr. Medical Science Liaison
Greenwich Biosciences, Inc.
1. Mead A. Front Plant Sci. 2019;10:697.
This supplement to Neurology Reviews summarizes summarize findings from English-only, peer-reviewed original articles and meta-analyses of specified cannabinoids’ effect on cognition in preclinical and clinical literature, where known, to guide practitioners with proper evidence and highlighting gaps in knowledge for future research.
Click here to read the supplement.
Authors
Francesca Filbey, PhD
Bert Moore Chair and Professor
of Cognition and Neuroscience
The University of Texas at Dallas
Chris Hauser, PhD
Medical Science Liaison
Greenwich Biosciences, Inc.
Karthik Rajasekaran, PhD
Sr. Medical Science Liaison
Greenwich Biosciences, Inc.
1. Mead A. Front Plant Sci. 2019;10:697.
Assessing Spinal Muscular Atrophy Across the Patient Journey
Click here to read.
Supplement Faculty
Perry Shieh, MD, PhD
Professor
Department of Neurology
David Geffen School
of Medicine at UCLA
Ronald Reagan UCLA
Medical Center
Los Angeles, CA
Sally Dunaway Young, PT, DPT
Physical Therapist
and Clinical Research
Evaluator/Manager
Stanford University School
of Medicine
Stanford, CA
Click here to read.
Supplement Faculty
Perry Shieh, MD, PhD
Professor
Department of Neurology
David Geffen School
of Medicine at UCLA
Ronald Reagan UCLA
Medical Center
Los Angeles, CA
Sally Dunaway Young, PT, DPT
Physical Therapist
and Clinical Research
Evaluator/Manager
Stanford University School
of Medicine
Stanford, CA
Click here to read.
Supplement Faculty
Perry Shieh, MD, PhD
Professor
Department of Neurology
David Geffen School
of Medicine at UCLA
Ronald Reagan UCLA
Medical Center
Los Angeles, CA
Sally Dunaway Young, PT, DPT
Physical Therapist
and Clinical Research
Evaluator/Manager
Stanford University School
of Medicine
Stanford, CA
VEGF Inhibitors and Ophthalmic Diseases
Click here to read the supplement.
Author
Retina Specialist
Rocky Mountain Retinal Consultants
Salt Lake City, UT
1. Apte RS, Chen DS, Ferrara N. VEGF in signaling and disease: beyond discovery and development. Cell. 2019;176(6):1248-1264.
Click here to read the supplement.
Author
Retina Specialist
Rocky Mountain Retinal Consultants
Salt Lake City, UT
1. Apte RS, Chen DS, Ferrara N. VEGF in signaling and disease: beyond discovery and development. Cell. 2019;176(6):1248-1264.
Click here to read the supplement.
Author
Retina Specialist
Rocky Mountain Retinal Consultants
Salt Lake City, UT
1. Apte RS, Chen DS, Ferrara N. VEGF in signaling and disease: beyond discovery and development. Cell. 2019;176(6):1248-1264.
Update: MS in Underserved Populations
As the United States population becomes increasingly diverse, the population of Americans living with neurological diseases such as multiple sclerosis (MS) will have more varied needs and greater health care inequities that may drive poorer outcomes.
In this supplement to Federal Practitioner, Victor M. Rivera, MD, FAAN, Mitzi Joi Williams, MD, and Patricia Pagnotta, ARNP-C, MSN, CNRN, MSCN discuss MS in minority populations such as African Americans, Hispanic Americans, and the military-veteran population. Topics include population-specific risk factors, disparities in clinical trial participation, and recommendations for improved MS management.
This supplement is sponsored by Biogen.
As the United States population becomes increasingly diverse, the population of Americans living with neurological diseases such as multiple sclerosis (MS) will have more varied needs and greater health care inequities that may drive poorer outcomes.
In this supplement to Federal Practitioner, Victor M. Rivera, MD, FAAN, Mitzi Joi Williams, MD, and Patricia Pagnotta, ARNP-C, MSN, CNRN, MSCN discuss MS in minority populations such as African Americans, Hispanic Americans, and the military-veteran population. Topics include population-specific risk factors, disparities in clinical trial participation, and recommendations for improved MS management.
This supplement is sponsored by Biogen.
As the United States population becomes increasingly diverse, the population of Americans living with neurological diseases such as multiple sclerosis (MS) will have more varied needs and greater health care inequities that may drive poorer outcomes.
In this supplement to Federal Practitioner, Victor M. Rivera, MD, FAAN, Mitzi Joi Williams, MD, and Patricia Pagnotta, ARNP-C, MSN, CNRN, MSCN discuss MS in minority populations such as African Americans, Hispanic Americans, and the military-veteran population. Topics include population-specific risk factors, disparities in clinical trial participation, and recommendations for improved MS management.
This supplement is sponsored by Biogen.
Migraine Management: What Primary Care Providers Need to Know
Migraine is a long-term, disabling neurologic disease that has a severe impact on the lives of patients living with it.1-3 Patients who experience frequent migraine attacks may require a multidisciplinary approach, which includes a combination of acute and preventive modalities as well as behavioral interventions as part of their treatment plan.4
This sponsored content shares ways in which patients with migraine may successfully manage their conditions and minimize impact on their lives with the support of their health care teams within primary care.4
References:
1 Lipton RB, Bigal ME, Diamond M, Freitag F, Reed ML, Stewart WF. Neurology. 2007;68(5):343-349.
2 Buse DC, Rupnow MFT, Lipton RB. Mayo Clin Proc. 2009;84(5):422-435.
3 GBD 2017 Disease and Injury Incidence and Prevalence Collaborators. Lancet. 2018;392(10159):1789-1858.
4 American Headache Society. Headache. 2019;59(1):1-18.
USA-334-83662
Migraine is a long-term, disabling neurologic disease that has a severe impact on the lives of patients living with it.1-3 Patients who experience frequent migraine attacks may require a multidisciplinary approach, which includes a combination of acute and preventive modalities as well as behavioral interventions as part of their treatment plan.4
This sponsored content shares ways in which patients with migraine may successfully manage their conditions and minimize impact on their lives with the support of their health care teams within primary care.4
References:
1 Lipton RB, Bigal ME, Diamond M, Freitag F, Reed ML, Stewart WF. Neurology. 2007;68(5):343-349.
2 Buse DC, Rupnow MFT, Lipton RB. Mayo Clin Proc. 2009;84(5):422-435.
3 GBD 2017 Disease and Injury Incidence and Prevalence Collaborators. Lancet. 2018;392(10159):1789-1858.
4 American Headache Society. Headache. 2019;59(1):1-18.
USA-334-83662
Migraine is a long-term, disabling neurologic disease that has a severe impact on the lives of patients living with it.1-3 Patients who experience frequent migraine attacks may require a multidisciplinary approach, which includes a combination of acute and preventive modalities as well as behavioral interventions as part of their treatment plan.4
This sponsored content shares ways in which patients with migraine may successfully manage their conditions and minimize impact on their lives with the support of their health care teams within primary care.4
References:
1 Lipton RB, Bigal ME, Diamond M, Freitag F, Reed ML, Stewart WF. Neurology. 2007;68(5):343-349.
2 Buse DC, Rupnow MFT, Lipton RB. Mayo Clin Proc. 2009;84(5):422-435.
3 GBD 2017 Disease and Injury Incidence and Prevalence Collaborators. Lancet. 2018;392(10159):1789-1858.
4 American Headache Society. Headache. 2019;59(1):1-18.
USA-334-83662
Migraine: More Than Just a Headache
Though a common neurologic disease with substantial impact, migraine is underdiagnosed and undertreated.1,2 The American Migraine Prevalence and Prevention study of 18,968 people found that approximately 44% of subjects who met the International Classification of Headache Disorders 2nd edition (ICHD-2) criteria for migraine had never received a medical diagnosis of
migraine.2
This sponsored content discusses the pathophysiology, characteristic symptoms, and burden of migraine, as well as how to help facilitate the diagnosis of migraine in the primary care setting.
This content is sponsored by Amgen Inc. and Novartis Pharmaceuticals Corporation.
Reference:
1 GBD 2017 Disease and Injury Incidence and Prevalence Collaborators. Lancet. 2018;392(10159): 1789-1858.
2 Diamond S, Bigal ME, Silberstein S, Loder E, Reed M, Lipton RB. Headache. 2007;47(3):355-363.
USA-334-83661
Though a common neurologic disease with substantial impact, migraine is underdiagnosed and undertreated.1,2 The American Migraine Prevalence and Prevention study of 18,968 people found that approximately 44% of subjects who met the International Classification of Headache Disorders 2nd edition (ICHD-2) criteria for migraine had never received a medical diagnosis of
migraine.2
This sponsored content discusses the pathophysiology, characteristic symptoms, and burden of migraine, as well as how to help facilitate the diagnosis of migraine in the primary care setting.
This content is sponsored by Amgen Inc. and Novartis Pharmaceuticals Corporation.
Reference:
1 GBD 2017 Disease and Injury Incidence and Prevalence Collaborators. Lancet. 2018;392(10159): 1789-1858.
2 Diamond S, Bigal ME, Silberstein S, Loder E, Reed M, Lipton RB. Headache. 2007;47(3):355-363.
USA-334-83661
Though a common neurologic disease with substantial impact, migraine is underdiagnosed and undertreated.1,2 The American Migraine Prevalence and Prevention study of 18,968 people found that approximately 44% of subjects who met the International Classification of Headache Disorders 2nd edition (ICHD-2) criteria for migraine had never received a medical diagnosis of
migraine.2
This sponsored content discusses the pathophysiology, characteristic symptoms, and burden of migraine, as well as how to help facilitate the diagnosis of migraine in the primary care setting.
This content is sponsored by Amgen Inc. and Novartis Pharmaceuticals Corporation.
Reference:
1 GBD 2017 Disease and Injury Incidence and Prevalence Collaborators. Lancet. 2018;392(10159): 1789-1858.
2 Diamond S, Bigal ME, Silberstein S, Loder E, Reed M, Lipton RB. Headache. 2007;47(3):355-363.
USA-334-83661
First-Line Treatment of IDA in NDD-CKD
In this supplement to Internal Medicine News, Kamyar Kalantar-Zadeh, MD, MPH, PhD, discusses a first-line treatment option for iron deficiency anemia (IDA) in patients with non-dialysis-dependent chronic kidney disease (NDD-CKD). Topics include:
- The interplay between IDA and CKD
- Recognizing IDA in patients with CKD
- First-line treatment efficacy and safety information
In this supplement to Internal Medicine News, Kamyar Kalantar-Zadeh, MD, MPH, PhD, discusses a first-line treatment option for iron deficiency anemia (IDA) in patients with non-dialysis-dependent chronic kidney disease (NDD-CKD). Topics include:
- The interplay between IDA and CKD
- Recognizing IDA in patients with CKD
- First-line treatment efficacy and safety information
In this supplement to Internal Medicine News, Kamyar Kalantar-Zadeh, MD, MPH, PhD, discusses a first-line treatment option for iron deficiency anemia (IDA) in patients with non-dialysis-dependent chronic kidney disease (NDD-CKD). Topics include:
- The interplay between IDA and CKD
- Recognizing IDA in patients with CKD
- First-line treatment efficacy and safety information
The Changing Landscape of Acute Migraine
Acute migraine onset results in 1.2 million emergency room visits and costs Americans $36 billion in health care expenditures annually, with the additional financial toll of 157 million lost workdays and unknown damage incurred by associated psychologic comorbidities.
In this supplement, Robert Cowan, MD discusses the latest understanding of acute migraine etiology, as well as updates in diagnostics, clinical trial design, and treatment options.
Acute migraine onset results in 1.2 million emergency room visits and costs Americans $36 billion in health care expenditures annually, with the additional financial toll of 157 million lost workdays and unknown damage incurred by associated psychologic comorbidities.
In this supplement, Robert Cowan, MD discusses the latest understanding of acute migraine etiology, as well as updates in diagnostics, clinical trial design, and treatment options.
Acute migraine onset results in 1.2 million emergency room visits and costs Americans $36 billion in health care expenditures annually, with the additional financial toll of 157 million lost workdays and unknown damage incurred by associated psychologic comorbidities.
In this supplement, Robert Cowan, MD discusses the latest understanding of acute migraine etiology, as well as updates in diagnostics, clinical trial design, and treatment options.
