COVID-19: A Dermatologist’s Experience From the US Epicenter

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The 1918 H1N1 influenza pandemic was the most severe pandemic in recent history. Fifty to 100 million individuals died worldwide, with approximately 675,000 deaths in the United States.1-3 The fatality rate was approximately 2% and was highest during the second and third waves of the disease.4 At that time, there were no diagnostic tests for influenza infection, influenza vaccines, antiviral drugs, antibiotics to treat secondary bacterial infections, or mechanical ventilation. Some cities decided to close schools, limit public gatherings, self-isolate, and issue quarantine orders; the federal government took no central role.

The 1918 influenza pandemic seems far away in history, but my mother often tells me stories about her own grandmother who disliked shaking anyone’s hands and would worry when people coughed or sneezed around her. It sounded like she was overreacting. Now, we can better relate to her concerns. Life has changed dramatically.

In mid-February 2020, news spread that the coronavirus disease 2019 (COVID-19) had spread from Wuhan, China, to a number of countries in Asia and the Middle East. I was following the news with great sadness for those affected countries, especially for Iran, my country of origin, which had become an epicenter of COVID-19. We were not worried for ourselves in the United States. These infections seemed far away. However, once Italy became the new epicenter of COVID-19 with alarmingly high death rates, I grasped the inevitable reality: The novel coronavirus would not spare the United States and would not spare New York.

Then the virus arrived in New York City. On March 10, 2020, our hospital recommended using teledermatology instead of in-person visits in an attempt to keep patients safe in their own homes. Cases of COVID-19 were escalating, hospitals were filling up, health care workers were falling ill, and there was a shortage of health care staff and personal protective equipment (PPE). Dermatologists at various hospitals were asked to retrain to help care for COVID-19 patients.

On March 13, flights from Europe to the United States were suspended. A statewide stay-at-home order subsequently went into effect on March 22. It felt surreal. From March 23 on, various specialty physicians and nurses in our hospital volunteered to work as frontline staff in the newly prepared annex where patients with possible COVID-19 would arrive. My dermatology co-residents and I started working as frontline physicians. Everything we had heard from the countries affected first had become our reality. Our hospital, part of the largest public health care system in the nation, became a dedicated COVID-19 treatment center.

Large numbers of scared patients with symptoms of COVID-19 flooded the annex. We sent the majority of them home, unable to offer them even a diagnostic test, and advised them to stay isolated. We only had the capacity to test those who required hospital admission.

It broke my heart even more when my colleagues became patients. We often felt helpless, not being able to help every patient and not being able to help our infected colleagues.

Elective surgeries were suspended. Inpatient beds, including specialized intensive care unit beds, rapidly filled up with COVID-19 patients. To help with the surge of patients, our hospital added medical and intensive care unit beds. The hospital became surreal, the corridors eerily empty and silent while every bed was filled, and health care workers were rushing around the inpatient units.

Life quickly became filled with fears—worries about how sick the patients would be, how much we would be able to help them, whether we would have enough PPE, who among our friends or family might be infected next, and whether we might ourselves be next. As PPE became scarce, I desperately searched for some form of protective equipment. I hunted for protective masks, face shields, eye protection, and gowns. We had to reuse disposable N95 masks and face shields multiple times and disinfect them as best we could. Our attendings ordered any protective gear they could find for us. Nearly everything was sold out; the very few items remaining would not for arrive for months. I could have never imagined that I would be afraid of going to work, of not having the appropriate protective gear, and that any day might be my last because of my profession.

New York City had become the epicenter of COVID-19. The city, the country, and the world were in chaos. Hospitals were overflowing, and makeshift morgues were appearing outside of hospitals. Those who could fled the city. Despite warnings from experts, we were not prepared. The number of deaths was climbing rapidly. There was no clarity on who could be tested or how to get it done. It felt like a nightmare.

Social distancing was in place, nonessential businesses were shut down, street vendors disappeared, and people were advised to wear face coverings. People were afraid of each other, afraid of getting too close and catching the virus. New York City—The City That Never Sleeps—went into deep sleep. Every day brought ever greater numbers of infected patients and more deaths.



Every day at 7:00 pm, people in New York City started clapping from their windows to salute health care workers, bringing tears to my eyes—tears for the gratitude of people mixed with tears of fear for my life and the lives of my patients and colleagues. I made arrangements for the event of falling ill, including a list of names and contact details of my family and close friends so they could be reached in case I ended up in intensive care or died.

After around 2 months of lockdown, New York City passed its peak, and the epicenter moved on. The current death toll (ie, confirmed deaths due to COVID-19) in New York stands at 18,836, while the reported death toll in the United States is 143,868, according to the Centers for Disease Control and Prevention. New York City has started a phased reopening to a new normal. Elective care has resumed, and people are leaving their homes again, eager to bring some sense of normalcy back into their lives.

I fear for those who will contract the virus in the next wave. I wonder what we will have learned.



Acknowledgment
The author wishes to thank Steven R. Feldman, MD, PhD (Winston-Salem, North Carolina), for his friendship and invaluable assistance with the conception and editing of this manuscript.

References
  1. Taubenberger JK. The origin and virulence of the 1918 “Spanish” influenza virus. Proc Am Philos Soc. 2006;150:86-112.
  2. Morens DM, Taubenberger JK. The mother of all pandemics is 100 years old (and going strong)! Am J Public Health. 2018;108:1449-1454.
  3. Johnson NPAS, Mueller J. Updating the accounts: global mortality of the 1918-1920 “Spanish” influenza pandemic. Bull Hist Med. 2002;76:105-115.
  4. Morens DM, Fauci AS. The 1918 influenza pandemic: insights for the 21st century. J Infect Dis. 2007;195:1018-1028.
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Dr. Mansouri is from the Department of Dermatology, NYC Health + Hospitals/Metropolitan, New York.

The author reports no conflict of interest.

Correspondence: Yasaman Mansouri, MD, MRCP, Department of Dermatology, Metropolitan Hospital, 1901 First Ave, New York, NY 10029 ([email protected]).

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Dr. Mansouri is from the Department of Dermatology, NYC Health + Hospitals/Metropolitan, New York.

The author reports no conflict of interest.

Correspondence: Yasaman Mansouri, MD, MRCP, Department of Dermatology, Metropolitan Hospital, 1901 First Ave, New York, NY 10029 ([email protected]).

Author and Disclosure Information

Dr. Mansouri is from the Department of Dermatology, NYC Health + Hospitals/Metropolitan, New York.

The author reports no conflict of interest.

Correspondence: Yasaman Mansouri, MD, MRCP, Department of Dermatology, Metropolitan Hospital, 1901 First Ave, New York, NY 10029 ([email protected]).

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The 1918 H1N1 influenza pandemic was the most severe pandemic in recent history. Fifty to 100 million individuals died worldwide, with approximately 675,000 deaths in the United States.1-3 The fatality rate was approximately 2% and was highest during the second and third waves of the disease.4 At that time, there were no diagnostic tests for influenza infection, influenza vaccines, antiviral drugs, antibiotics to treat secondary bacterial infections, or mechanical ventilation. Some cities decided to close schools, limit public gatherings, self-isolate, and issue quarantine orders; the federal government took no central role.

The 1918 influenza pandemic seems far away in history, but my mother often tells me stories about her own grandmother who disliked shaking anyone’s hands and would worry when people coughed or sneezed around her. It sounded like she was overreacting. Now, we can better relate to her concerns. Life has changed dramatically.

In mid-February 2020, news spread that the coronavirus disease 2019 (COVID-19) had spread from Wuhan, China, to a number of countries in Asia and the Middle East. I was following the news with great sadness for those affected countries, especially for Iran, my country of origin, which had become an epicenter of COVID-19. We were not worried for ourselves in the United States. These infections seemed far away. However, once Italy became the new epicenter of COVID-19 with alarmingly high death rates, I grasped the inevitable reality: The novel coronavirus would not spare the United States and would not spare New York.

Then the virus arrived in New York City. On March 10, 2020, our hospital recommended using teledermatology instead of in-person visits in an attempt to keep patients safe in their own homes. Cases of COVID-19 were escalating, hospitals were filling up, health care workers were falling ill, and there was a shortage of health care staff and personal protective equipment (PPE). Dermatologists at various hospitals were asked to retrain to help care for COVID-19 patients.

On March 13, flights from Europe to the United States were suspended. A statewide stay-at-home order subsequently went into effect on March 22. It felt surreal. From March 23 on, various specialty physicians and nurses in our hospital volunteered to work as frontline staff in the newly prepared annex where patients with possible COVID-19 would arrive. My dermatology co-residents and I started working as frontline physicians. Everything we had heard from the countries affected first had become our reality. Our hospital, part of the largest public health care system in the nation, became a dedicated COVID-19 treatment center.

Large numbers of scared patients with symptoms of COVID-19 flooded the annex. We sent the majority of them home, unable to offer them even a diagnostic test, and advised them to stay isolated. We only had the capacity to test those who required hospital admission.

It broke my heart even more when my colleagues became patients. We often felt helpless, not being able to help every patient and not being able to help our infected colleagues.

Elective surgeries were suspended. Inpatient beds, including specialized intensive care unit beds, rapidly filled up with COVID-19 patients. To help with the surge of patients, our hospital added medical and intensive care unit beds. The hospital became surreal, the corridors eerily empty and silent while every bed was filled, and health care workers were rushing around the inpatient units.

Life quickly became filled with fears—worries about how sick the patients would be, how much we would be able to help them, whether we would have enough PPE, who among our friends or family might be infected next, and whether we might ourselves be next. As PPE became scarce, I desperately searched for some form of protective equipment. I hunted for protective masks, face shields, eye protection, and gowns. We had to reuse disposable N95 masks and face shields multiple times and disinfect them as best we could. Our attendings ordered any protective gear they could find for us. Nearly everything was sold out; the very few items remaining would not for arrive for months. I could have never imagined that I would be afraid of going to work, of not having the appropriate protective gear, and that any day might be my last because of my profession.

New York City had become the epicenter of COVID-19. The city, the country, and the world were in chaos. Hospitals were overflowing, and makeshift morgues were appearing outside of hospitals. Those who could fled the city. Despite warnings from experts, we were not prepared. The number of deaths was climbing rapidly. There was no clarity on who could be tested or how to get it done. It felt like a nightmare.

Social distancing was in place, nonessential businesses were shut down, street vendors disappeared, and people were advised to wear face coverings. People were afraid of each other, afraid of getting too close and catching the virus. New York City—The City That Never Sleeps—went into deep sleep. Every day brought ever greater numbers of infected patients and more deaths.



Every day at 7:00 pm, people in New York City started clapping from their windows to salute health care workers, bringing tears to my eyes—tears for the gratitude of people mixed with tears of fear for my life and the lives of my patients and colleagues. I made arrangements for the event of falling ill, including a list of names and contact details of my family and close friends so they could be reached in case I ended up in intensive care or died.

After around 2 months of lockdown, New York City passed its peak, and the epicenter moved on. The current death toll (ie, confirmed deaths due to COVID-19) in New York stands at 18,836, while the reported death toll in the United States is 143,868, according to the Centers for Disease Control and Prevention. New York City has started a phased reopening to a new normal. Elective care has resumed, and people are leaving their homes again, eager to bring some sense of normalcy back into their lives.

I fear for those who will contract the virus in the next wave. I wonder what we will have learned.



Acknowledgment
The author wishes to thank Steven R. Feldman, MD, PhD (Winston-Salem, North Carolina), for his friendship and invaluable assistance with the conception and editing of this manuscript.

The 1918 H1N1 influenza pandemic was the most severe pandemic in recent history. Fifty to 100 million individuals died worldwide, with approximately 675,000 deaths in the United States.1-3 The fatality rate was approximately 2% and was highest during the second and third waves of the disease.4 At that time, there were no diagnostic tests for influenza infection, influenza vaccines, antiviral drugs, antibiotics to treat secondary bacterial infections, or mechanical ventilation. Some cities decided to close schools, limit public gatherings, self-isolate, and issue quarantine orders; the federal government took no central role.

The 1918 influenza pandemic seems far away in history, but my mother often tells me stories about her own grandmother who disliked shaking anyone’s hands and would worry when people coughed or sneezed around her. It sounded like she was overreacting. Now, we can better relate to her concerns. Life has changed dramatically.

In mid-February 2020, news spread that the coronavirus disease 2019 (COVID-19) had spread from Wuhan, China, to a number of countries in Asia and the Middle East. I was following the news with great sadness for those affected countries, especially for Iran, my country of origin, which had become an epicenter of COVID-19. We were not worried for ourselves in the United States. These infections seemed far away. However, once Italy became the new epicenter of COVID-19 with alarmingly high death rates, I grasped the inevitable reality: The novel coronavirus would not spare the United States and would not spare New York.

Then the virus arrived in New York City. On March 10, 2020, our hospital recommended using teledermatology instead of in-person visits in an attempt to keep patients safe in their own homes. Cases of COVID-19 were escalating, hospitals were filling up, health care workers were falling ill, and there was a shortage of health care staff and personal protective equipment (PPE). Dermatologists at various hospitals were asked to retrain to help care for COVID-19 patients.

On March 13, flights from Europe to the United States were suspended. A statewide stay-at-home order subsequently went into effect on March 22. It felt surreal. From March 23 on, various specialty physicians and nurses in our hospital volunteered to work as frontline staff in the newly prepared annex where patients with possible COVID-19 would arrive. My dermatology co-residents and I started working as frontline physicians. Everything we had heard from the countries affected first had become our reality. Our hospital, part of the largest public health care system in the nation, became a dedicated COVID-19 treatment center.

Large numbers of scared patients with symptoms of COVID-19 flooded the annex. We sent the majority of them home, unable to offer them even a diagnostic test, and advised them to stay isolated. We only had the capacity to test those who required hospital admission.

It broke my heart even more when my colleagues became patients. We often felt helpless, not being able to help every patient and not being able to help our infected colleagues.

Elective surgeries were suspended. Inpatient beds, including specialized intensive care unit beds, rapidly filled up with COVID-19 patients. To help with the surge of patients, our hospital added medical and intensive care unit beds. The hospital became surreal, the corridors eerily empty and silent while every bed was filled, and health care workers were rushing around the inpatient units.

Life quickly became filled with fears—worries about how sick the patients would be, how much we would be able to help them, whether we would have enough PPE, who among our friends or family might be infected next, and whether we might ourselves be next. As PPE became scarce, I desperately searched for some form of protective equipment. I hunted for protective masks, face shields, eye protection, and gowns. We had to reuse disposable N95 masks and face shields multiple times and disinfect them as best we could. Our attendings ordered any protective gear they could find for us. Nearly everything was sold out; the very few items remaining would not for arrive for months. I could have never imagined that I would be afraid of going to work, of not having the appropriate protective gear, and that any day might be my last because of my profession.

New York City had become the epicenter of COVID-19. The city, the country, and the world were in chaos. Hospitals were overflowing, and makeshift morgues were appearing outside of hospitals. Those who could fled the city. Despite warnings from experts, we were not prepared. The number of deaths was climbing rapidly. There was no clarity on who could be tested or how to get it done. It felt like a nightmare.

Social distancing was in place, nonessential businesses were shut down, street vendors disappeared, and people were advised to wear face coverings. People were afraid of each other, afraid of getting too close and catching the virus. New York City—The City That Never Sleeps—went into deep sleep. Every day brought ever greater numbers of infected patients and more deaths.



Every day at 7:00 pm, people in New York City started clapping from their windows to salute health care workers, bringing tears to my eyes—tears for the gratitude of people mixed with tears of fear for my life and the lives of my patients and colleagues. I made arrangements for the event of falling ill, including a list of names and contact details of my family and close friends so they could be reached in case I ended up in intensive care or died.

After around 2 months of lockdown, New York City passed its peak, and the epicenter moved on. The current death toll (ie, confirmed deaths due to COVID-19) in New York stands at 18,836, while the reported death toll in the United States is 143,868, according to the Centers for Disease Control and Prevention. New York City has started a phased reopening to a new normal. Elective care has resumed, and people are leaving their homes again, eager to bring some sense of normalcy back into their lives.

I fear for those who will contract the virus in the next wave. I wonder what we will have learned.



Acknowledgment
The author wishes to thank Steven R. Feldman, MD, PhD (Winston-Salem, North Carolina), for his friendship and invaluable assistance with the conception and editing of this manuscript.

References
  1. Taubenberger JK. The origin and virulence of the 1918 “Spanish” influenza virus. Proc Am Philos Soc. 2006;150:86-112.
  2. Morens DM, Taubenberger JK. The mother of all pandemics is 100 years old (and going strong)! Am J Public Health. 2018;108:1449-1454.
  3. Johnson NPAS, Mueller J. Updating the accounts: global mortality of the 1918-1920 “Spanish” influenza pandemic. Bull Hist Med. 2002;76:105-115.
  4. Morens DM, Fauci AS. The 1918 influenza pandemic: insights for the 21st century. J Infect Dis. 2007;195:1018-1028.
References
  1. Taubenberger JK. The origin and virulence of the 1918 “Spanish” influenza virus. Proc Am Philos Soc. 2006;150:86-112.
  2. Morens DM, Taubenberger JK. The mother of all pandemics is 100 years old (and going strong)! Am J Public Health. 2018;108:1449-1454.
  3. Johnson NPAS, Mueller J. Updating the accounts: global mortality of the 1918-1920 “Spanish” influenza pandemic. Bull Hist Med. 2002;76:105-115.
  4. Morens DM, Fauci AS. The 1918 influenza pandemic: insights for the 21st century. J Infect Dis. 2007;195:1018-1028.
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  • Coronavirus disease 2019 (COVID-19) can spread quickly, creating chaos in the health care system and leading to critical supply shortages within a short amount of time.
  • Social distancing, quarantine, and isolation appear to be powerful tools in reducing the spread of COVID-19.
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Update on Hyaluronic Acid Fillers for Facial Rejuvenation

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Update on Hyaluronic Acid Fillers for Facial Rejuvenation

Facial rejuvenation has become increasingly popular, with nonsurgical and noninvasive procedures comprising a large part of aesthetic practice. According to the American Society for Aesthetic Plastic Surgery, Americans spent $12 billion on cosmetic procedures in 2014, with more than 10 million surgical and nonsurgical procedures performed. The top 5 nonsurgical procedures for both men and women combined were botulinum toxin, hyaluronic acid (HA), hair removal, chemical peel, and microdermabrasion.1

The first dermal filler used was bovine collagen, which was approved by the US Food and Drug Administration (FDA) in 1981. Despite its efficacy in the correction of facial rhytides, bovine collagen required allergy testing prior to use and was discontinued in 2010. Dermal fillers have evolved over the years, and newer products that are superior to earlier fillers with regard to longevity, safety, and tolerability and that do not require allergy testing have become available; however, advances in the use of dermal fillers are not only related to the development of newer products but also to evolving injection techniques. Initially, the aim of treatment with dermal fillers was to correct lines and wrinkles, but an increased understanding of the complex changes that occur with aging have changed our approach to one of volume replacement, with an emphasis on volume restoration in the midface. This approach requires an in-depth understanding of facial anatomy as well as the interactions of the skin, soft tissue, muscle, and bone. Furthermore, placement of filler in specific fat compartments can provide a more natural appearance and an all-around youthful face.2 In this article, we discuss HA fillers that have gained FDA approval within the last 5 years (Table).

Overview of HA Fillers

Hyaluronic acid is a naturally occurring linear glycosaminoglycan with a disaccharide unit, which repeats several thousand times.3 Hyaluronic acid is an essential part of the extracellular matrix of many tissues including the dermis and plays an important role in tissue growth, development, and wound healing. Hyaluronic acid is hygroscopic and absorbs water extensively, thus creating volume.4 Treatment with HA fillers is popular, as they are biocompatible and have a low potential for allergic reactions. They also are easy to use and reversible.4 The first HA filler to gain FDA approval was Restylane (Galderma  Laboratories, LP). Currently, several HA fillers are approved in the United States, and each product differs from the others in polymer chain length, degree of HA concentration, particle size, gel consistency, gel hardness, gel viscosity, and degree of water solubility, as well as amount and degree of cross-linking. Cross-linking is essential to avoid enzymatic degradation by endogenous hyaluronidase when injected into the skin and thus to prolong the product’s half-life.5 Cross-linkers used to manufacture HA fillers include 1,4-butanediol diglycidyl ether and divinyl sulfone. More concentrated products with a greater degree of cross-linking provide increased longevity, but they are associated with a higher risk for inflammation and nodule formation. The elastic modulus (G′) is a measure of the firmness of dermal fillers, describing their resistance to deformation. Materials with a higher G′ are stiffer and are meant for deeper injections. Hyaluronic acid fillers can be further classified as biphasic or monophasic. Biphasic fillers (eg, Restylane, Perlane [Galderma Laboratories, LP]) contain a range of microsphere sizes, while monophasic fillers (eg, Juvéderm [Allergan, Inc], Belotero Balance [Merz North America, Inc]) contain homogeneous microspheres. Although randomized clinical trials have reported comparable efficacy and durability of biphasic and monophasic fillers when used to treat the nasolabial folds,6-8 monophasic HA fillers are more cohesive and may not migrate as much following injection.

Restylane Family

Restylane was the first FDA-approved HA filler, gaining its approval in 2003. Restylane is a nonanimal stabilized HA (NASHA) that is produced from the fermentation of equine streptococci. It is cross-linked with 1,4-butanediol diglycidyl ether with a 1% degree of cross-linking. Restylane has an HA concentration of 20 mg/mL. The particle size range of Restylane and Restylane-L is 330 to 430 mm. Restylane (and also Perlane) get passed through sizing screens via sieves and are quantified by their size. The longevity of HA fillers is approximately 6 months; however, various factors affect the product’s longevity, such as the degree of cross-linking, treatment area, and the patient’s metabolism. Restylane-L, which was FDA approved in 2012, is a newer product with 0.3% lidocaine incorporated into the syringe itself. It was the first product from the Restylane range to be approved for lip augmentation. The addition of lidocaine (designated by the L in the product name) does not affect the longevity of a filler.9

The newest FDA-approved HA filler was Restylane Silk (approved in 2014), which has been specifically designed for lip augmentation and correction of perioral rhytides. To avoid postprocedural swelling, it generally is recommended that Restylane Silk be injected slowly. If required, a short course of oral prednisone may be administered after the procedure to treat any edema. Restylane Silk is less viscous than Restylane and requires less pressure to inject. Therefore, it is more suited for treatment of fine perioral lines, as it flows more easily. Because it contains 0.3% lidocaine, discomfort usually is minimal, with treatment lasting approximately 30 to 60 minutes. In the author’s experience (G.G.), Restylane Silk provides a softer correction, though one has to be careful to inject slowly to avoid postinjection swelling. Restylane Silk also may be suitable for neck rejuvenation (off label), but several treatment sessions usually are required. Patients should be warned that they are likely to experience ecchymoses. In our experience, the effects of Restylane Silk injections last approximately 6 to 9 months.

 

 

Juvéderm Family

The first Juvéderm product was approved by the FDA in 2006. Juvéderm is a bacterium-derived NASHA. Injectable gel formulations of Juvéderm, including Juvéderm Ultra and Juvéderm Ultra Plus, are FDA approved for the correction of moderate to severe facial wrinkles and folds. The first products in the Juvéderm line were produced using a technology called Hylacross technology, with cohesive molecules of cross-linked HA. In contrast to the sizing technology used by Restylane and Perlane, the Hylacross technology does not break up the cross-linked HA by passing the product through sizing screens via sieves, but instead produces monophasic gels. These Juvéderm products have a high concentration of cross-linked HAs, which accounts for their longevity, and they are soft and easy to use.

Juvéderm Voluma XC was FDA approved in 2013. It is a 20-mg/mL, smooth, highly cohesive, viscous HA, gel that is manufactured using Vycross technology, a combination of low- and high-molecular-weight HA, and it is the only HA filler that is indicated for deep injection for cheek augmentation,10 as it creates a lift due to its higher G′ and a low swelling capacity, with results lasting up to 2 years. The mean volume administered over the initial 4-week period of one study was 5.1 mL.11

Belotero Balance

Belotero Balance was approved by the FDA in 2011 for the correction of moderate to severe facial wrinkles and folds (eg, nasolabial folds).12 Belotero Balance is an HA filler with a cohesive polydensified matrix technology and low elasticity and viscosity. It has the lowest G′ of the currently available dermal fillers12 and therefore is associated with increased injection precision. Belotero Balance is ideal for superficial injections,13 such as forehead lines, vermilion border, tear trough, atrophic scars, and neck lines (off label). Some clinicians reconstitute Belotero Balance with lidocaine (off label) to provide a more pain-free procedure. In our experience, results typically last at least 6 to 8 months.

Complications

Hyaluronic acid fillers share the same adverse events across the product lines. The most common reactions include erythema, swelling, and bruising, which often are unavoidable and may be considered expected effects. Less-frequent events include contour irregularities; product migration; bluish discoloration known as the Tyndall effect, which is more likely to occur with superficial injections; nodules; infection at the injection site; scarring; and vascular occlusion, potentially leading to blindness.14 These more severe complications often can be avoided. Appropriate skin preparation and a sterile technique are critical in preventing infections, while deep placement of filler material reduces the risk for Tyndall effect, nodules, and scarring. Skin necrosis occurs by external compression of the blood supply by the product or occlusion via direct injection into a vessel. Aspirating prior to injection, administering lower volumes, and tenting the skin to inject more superficially can reduce the risk for skin necrosis. Every clinician needs to be able to rapidly recognize the signs of necrosis and to administer urgent therapy, such as the application of warm gauze and nitroglycerin paste, tapping the area to facilitate vasodilatation, and injecting hyaluronidase when required.

On the Horizon

Other dermal fillers that may gain FDA approval in the next few years include Teosyal (Laboratories  Teoxane Geneva),6 a new range of monophasic NASHA products that provide high viscosity and elasticity with results lasting 6 to 9 months, and potentially Juvéderm Volbella, a smooth, nonparticle, viscous HA gel developed specifically for the lip area with results lasting up to 1 year.15

Conclusion

Over the last decade, the popularity of dermal fillers has steadily increased, and fillers have become a cornerstone of aesthetic medicine. The increased number of available products necessitates thorough knowledge by the treating physician to ensure optimal outcomes. There is no universal filler that can achieve ideal outcomes in all anatomic sites or in all patients. Often a combination approach may be ideal, such as the use of a product with a higher G′ for re-volumization, followed by a filler with a lower G′ for superficial injection. Some patients may also benefit from a combination of both dermal fillers and neurotoxin injections, either on the same day or at separate visits, which may increase the longevity of the filler.

References

1. The American Society for Aesthetic Plastic Surgery reports Americans spent more than 12 billion in 2014; procedures for men up 43% over five year period [news release]. New York, NY: American Society for Aesthetic Plastic Surgery; March 11, 2015. http://www.surgery.org/media/news-releases/the-american-society-for-aesthetic-plastic-surgery-reports-americans-spent-more-than-12-billion-in-2014--pro. Accessed July 7, 2015.

2. Fitzgerald R, Rubin AG. Filler placement and the fat compartments. Dermatol Clin. 2014;32:37-50.

3. Cowman MK, Matsuoka S. Experimental approaches to hyaluronan structure. Carbohydr Res. 2005;340:791-809.

4. Lee A, Grummer SE, Kriegel D, et al. Hyaluronidase. Dermatol Surg. 2010;36:1071-1077.

5. Kablik J, Monheit GD, Yu L, et al. Comparative physical properties of hyaluronic acid dermal fillers. Dermatol Surg. 2009;35(suppl 1):302-312.

6. Nast A, Reytan N, Hartmann V, et al. Efficacy and durability of two hyaluronic acid-based fillers in the correction of nasolabial folds: results of a prospective, randomized, double-blind, actively controlled clinical pilot study. Dermatol Surg. 2011;37:768-775.

7. Ascher B, Bayerl C, Brun P, et al. Efficacy and safety of a new hyaluronic acid dermal filler in the treatment of severe nasolabial lines: 6-month interim results of a randomized, evaluator-blinded, intra-individual comparison study. J Cosmet Dermatol. 2011;10:94-98.

8. Rzany B, Bayerl C, Bodokh I, et al. Efficacy and safety of a new hyaluronic acid dermal filler in the treatment of moderate nasolabial folds: 6-month interim results of a randomized, evaluator-blinded, intra-individual comparison study. J Cosmet Laser Ther. 2011;13:107-112.

9. Lupo MP, Swetman G, Waller W. The effect of lidocaine when mixed with large gel particle hyaluronic acid filler tolerability and longevity: a six-month trial. J Drugs Dermatol. 2010;9:1097-1100.

10. Ho D, Jagdeo J. Biological properties of a new volumizing hyaluronic acid filler: a systematic review. J Drugs Dermatol. 2015;14:50-54.

11. Callan P, Goodman GJ, Carlisle I, et al. Efficacy and safety of a hyaluronic acid filler in subjects treated for correction of midface volume deficiency: a 24 month study. Clin Cosmet Investig Dermatol. 2013;6:81-89.

12. Hevia O, Cohen BH, Howell DJ. Safety and efficacy of a cohesive polydensified matrix hyaluronic acid for the correction of infraorbital hollow: an observational study with results at 40 weeks. J Drugs Dermatol. 2014;13:1030-1036.

13. Lorenc ZP, Fagien S, Flynn TC, et al. Clinical application and assessment of Belotero: a roundtable discussion. Plast Reconstr Surg. 2013;132(4, suppl 2):69S-76S.

14. Carruthers JD, Fagien S, Rohrich RJ, et al. Blindness caused by cosmetic filler injection: a review of cause and therapy. Plast Reconstr Surg. 2014;134:1197-1201.

15. Eccleston D, Murphy DK. Juvéderm(®) Volbella™ in the perioral area: a 12-month prospective, multicenter, open-label study. Clin Cosmet Investig Dermatol. 2012;5:167-172.

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Yasaman Mansouri, MD, MRCP; Gary Goldenberg, MD

From the Department of Dermatology, Icahn School of Medicine at Mount Sinai, New York, New York.

Dr. Mansouri reports no conflict of interest, but her contribution was supported by the Geoffrey Dowling Fellowship, a grant from the British Association of Dermatologists (United Kingdom). Dr. Goldenberg reports no conflict of interest.

Correspondence: Gary Goldenberg, MD, 5 E 98th St, 5th Floor, New York, NY 10029-6574 ([email protected]).

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Author and Disclosure Information

Yasaman Mansouri, MD, MRCP; Gary Goldenberg, MD

From the Department of Dermatology, Icahn School of Medicine at Mount Sinai, New York, New York.

Dr. Mansouri reports no conflict of interest, but her contribution was supported by the Geoffrey Dowling Fellowship, a grant from the British Association of Dermatologists (United Kingdom). Dr. Goldenberg reports no conflict of interest.

Correspondence: Gary Goldenberg, MD, 5 E 98th St, 5th Floor, New York, NY 10029-6574 ([email protected]).

Author and Disclosure Information

Yasaman Mansouri, MD, MRCP; Gary Goldenberg, MD

From the Department of Dermatology, Icahn School of Medicine at Mount Sinai, New York, New York.

Dr. Mansouri reports no conflict of interest, but her contribution was supported by the Geoffrey Dowling Fellowship, a grant from the British Association of Dermatologists (United Kingdom). Dr. Goldenberg reports no conflict of interest.

Correspondence: Gary Goldenberg, MD, 5 E 98th St, 5th Floor, New York, NY 10029-6574 ([email protected]).

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Related Articles

Facial rejuvenation has become increasingly popular, with nonsurgical and noninvasive procedures comprising a large part of aesthetic practice. According to the American Society for Aesthetic Plastic Surgery, Americans spent $12 billion on cosmetic procedures in 2014, with more than 10 million surgical and nonsurgical procedures performed. The top 5 nonsurgical procedures for both men and women combined were botulinum toxin, hyaluronic acid (HA), hair removal, chemical peel, and microdermabrasion.1

The first dermal filler used was bovine collagen, which was approved by the US Food and Drug Administration (FDA) in 1981. Despite its efficacy in the correction of facial rhytides, bovine collagen required allergy testing prior to use and was discontinued in 2010. Dermal fillers have evolved over the years, and newer products that are superior to earlier fillers with regard to longevity, safety, and tolerability and that do not require allergy testing have become available; however, advances in the use of dermal fillers are not only related to the development of newer products but also to evolving injection techniques. Initially, the aim of treatment with dermal fillers was to correct lines and wrinkles, but an increased understanding of the complex changes that occur with aging have changed our approach to one of volume replacement, with an emphasis on volume restoration in the midface. This approach requires an in-depth understanding of facial anatomy as well as the interactions of the skin, soft tissue, muscle, and bone. Furthermore, placement of filler in specific fat compartments can provide a more natural appearance and an all-around youthful face.2 In this article, we discuss HA fillers that have gained FDA approval within the last 5 years (Table).

Overview of HA Fillers

Hyaluronic acid is a naturally occurring linear glycosaminoglycan with a disaccharide unit, which repeats several thousand times.3 Hyaluronic acid is an essential part of the extracellular matrix of many tissues including the dermis and plays an important role in tissue growth, development, and wound healing. Hyaluronic acid is hygroscopic and absorbs water extensively, thus creating volume.4 Treatment with HA fillers is popular, as they are biocompatible and have a low potential for allergic reactions. They also are easy to use and reversible.4 The first HA filler to gain FDA approval was Restylane (Galderma  Laboratories, LP). Currently, several HA fillers are approved in the United States, and each product differs from the others in polymer chain length, degree of HA concentration, particle size, gel consistency, gel hardness, gel viscosity, and degree of water solubility, as well as amount and degree of cross-linking. Cross-linking is essential to avoid enzymatic degradation by endogenous hyaluronidase when injected into the skin and thus to prolong the product’s half-life.5 Cross-linkers used to manufacture HA fillers include 1,4-butanediol diglycidyl ether and divinyl sulfone. More concentrated products with a greater degree of cross-linking provide increased longevity, but they are associated with a higher risk for inflammation and nodule formation. The elastic modulus (G′) is a measure of the firmness of dermal fillers, describing their resistance to deformation. Materials with a higher G′ are stiffer and are meant for deeper injections. Hyaluronic acid fillers can be further classified as biphasic or monophasic. Biphasic fillers (eg, Restylane, Perlane [Galderma Laboratories, LP]) contain a range of microsphere sizes, while monophasic fillers (eg, Juvéderm [Allergan, Inc], Belotero Balance [Merz North America, Inc]) contain homogeneous microspheres. Although randomized clinical trials have reported comparable efficacy and durability of biphasic and monophasic fillers when used to treat the nasolabial folds,6-8 monophasic HA fillers are more cohesive and may not migrate as much following injection.

Restylane Family

Restylane was the first FDA-approved HA filler, gaining its approval in 2003. Restylane is a nonanimal stabilized HA (NASHA) that is produced from the fermentation of equine streptococci. It is cross-linked with 1,4-butanediol diglycidyl ether with a 1% degree of cross-linking. Restylane has an HA concentration of 20 mg/mL. The particle size range of Restylane and Restylane-L is 330 to 430 mm. Restylane (and also Perlane) get passed through sizing screens via sieves and are quantified by their size. The longevity of HA fillers is approximately 6 months; however, various factors affect the product’s longevity, such as the degree of cross-linking, treatment area, and the patient’s metabolism. Restylane-L, which was FDA approved in 2012, is a newer product with 0.3% lidocaine incorporated into the syringe itself. It was the first product from the Restylane range to be approved for lip augmentation. The addition of lidocaine (designated by the L in the product name) does not affect the longevity of a filler.9

The newest FDA-approved HA filler was Restylane Silk (approved in 2014), which has been specifically designed for lip augmentation and correction of perioral rhytides. To avoid postprocedural swelling, it generally is recommended that Restylane Silk be injected slowly. If required, a short course of oral prednisone may be administered after the procedure to treat any edema. Restylane Silk is less viscous than Restylane and requires less pressure to inject. Therefore, it is more suited for treatment of fine perioral lines, as it flows more easily. Because it contains 0.3% lidocaine, discomfort usually is minimal, with treatment lasting approximately 30 to 60 minutes. In the author’s experience (G.G.), Restylane Silk provides a softer correction, though one has to be careful to inject slowly to avoid postinjection swelling. Restylane Silk also may be suitable for neck rejuvenation (off label), but several treatment sessions usually are required. Patients should be warned that they are likely to experience ecchymoses. In our experience, the effects of Restylane Silk injections last approximately 6 to 9 months.

 

 

Juvéderm Family

The first Juvéderm product was approved by the FDA in 2006. Juvéderm is a bacterium-derived NASHA. Injectable gel formulations of Juvéderm, including Juvéderm Ultra and Juvéderm Ultra Plus, are FDA approved for the correction of moderate to severe facial wrinkles and folds. The first products in the Juvéderm line were produced using a technology called Hylacross technology, with cohesive molecules of cross-linked HA. In contrast to the sizing technology used by Restylane and Perlane, the Hylacross technology does not break up the cross-linked HA by passing the product through sizing screens via sieves, but instead produces monophasic gels. These Juvéderm products have a high concentration of cross-linked HAs, which accounts for their longevity, and they are soft and easy to use.

Juvéderm Voluma XC was FDA approved in 2013. It is a 20-mg/mL, smooth, highly cohesive, viscous HA, gel that is manufactured using Vycross technology, a combination of low- and high-molecular-weight HA, and it is the only HA filler that is indicated for deep injection for cheek augmentation,10 as it creates a lift due to its higher G′ and a low swelling capacity, with results lasting up to 2 years. The mean volume administered over the initial 4-week period of one study was 5.1 mL.11

Belotero Balance

Belotero Balance was approved by the FDA in 2011 for the correction of moderate to severe facial wrinkles and folds (eg, nasolabial folds).12 Belotero Balance is an HA filler with a cohesive polydensified matrix technology and low elasticity and viscosity. It has the lowest G′ of the currently available dermal fillers12 and therefore is associated with increased injection precision. Belotero Balance is ideal for superficial injections,13 such as forehead lines, vermilion border, tear trough, atrophic scars, and neck lines (off label). Some clinicians reconstitute Belotero Balance with lidocaine (off label) to provide a more pain-free procedure. In our experience, results typically last at least 6 to 8 months.

Complications

Hyaluronic acid fillers share the same adverse events across the product lines. The most common reactions include erythema, swelling, and bruising, which often are unavoidable and may be considered expected effects. Less-frequent events include contour irregularities; product migration; bluish discoloration known as the Tyndall effect, which is more likely to occur with superficial injections; nodules; infection at the injection site; scarring; and vascular occlusion, potentially leading to blindness.14 These more severe complications often can be avoided. Appropriate skin preparation and a sterile technique are critical in preventing infections, while deep placement of filler material reduces the risk for Tyndall effect, nodules, and scarring. Skin necrosis occurs by external compression of the blood supply by the product or occlusion via direct injection into a vessel. Aspirating prior to injection, administering lower volumes, and tenting the skin to inject more superficially can reduce the risk for skin necrosis. Every clinician needs to be able to rapidly recognize the signs of necrosis and to administer urgent therapy, such as the application of warm gauze and nitroglycerin paste, tapping the area to facilitate vasodilatation, and injecting hyaluronidase when required.

On the Horizon

Other dermal fillers that may gain FDA approval in the next few years include Teosyal (Laboratories  Teoxane Geneva),6 a new range of monophasic NASHA products that provide high viscosity and elasticity with results lasting 6 to 9 months, and potentially Juvéderm Volbella, a smooth, nonparticle, viscous HA gel developed specifically for the lip area with results lasting up to 1 year.15

Conclusion

Over the last decade, the popularity of dermal fillers has steadily increased, and fillers have become a cornerstone of aesthetic medicine. The increased number of available products necessitates thorough knowledge by the treating physician to ensure optimal outcomes. There is no universal filler that can achieve ideal outcomes in all anatomic sites or in all patients. Often a combination approach may be ideal, such as the use of a product with a higher G′ for re-volumization, followed by a filler with a lower G′ for superficial injection. Some patients may also benefit from a combination of both dermal fillers and neurotoxin injections, either on the same day or at separate visits, which may increase the longevity of the filler.

Facial rejuvenation has become increasingly popular, with nonsurgical and noninvasive procedures comprising a large part of aesthetic practice. According to the American Society for Aesthetic Plastic Surgery, Americans spent $12 billion on cosmetic procedures in 2014, with more than 10 million surgical and nonsurgical procedures performed. The top 5 nonsurgical procedures for both men and women combined were botulinum toxin, hyaluronic acid (HA), hair removal, chemical peel, and microdermabrasion.1

The first dermal filler used was bovine collagen, which was approved by the US Food and Drug Administration (FDA) in 1981. Despite its efficacy in the correction of facial rhytides, bovine collagen required allergy testing prior to use and was discontinued in 2010. Dermal fillers have evolved over the years, and newer products that are superior to earlier fillers with regard to longevity, safety, and tolerability and that do not require allergy testing have become available; however, advances in the use of dermal fillers are not only related to the development of newer products but also to evolving injection techniques. Initially, the aim of treatment with dermal fillers was to correct lines and wrinkles, but an increased understanding of the complex changes that occur with aging have changed our approach to one of volume replacement, with an emphasis on volume restoration in the midface. This approach requires an in-depth understanding of facial anatomy as well as the interactions of the skin, soft tissue, muscle, and bone. Furthermore, placement of filler in specific fat compartments can provide a more natural appearance and an all-around youthful face.2 In this article, we discuss HA fillers that have gained FDA approval within the last 5 years (Table).

Overview of HA Fillers

Hyaluronic acid is a naturally occurring linear glycosaminoglycan with a disaccharide unit, which repeats several thousand times.3 Hyaluronic acid is an essential part of the extracellular matrix of many tissues including the dermis and plays an important role in tissue growth, development, and wound healing. Hyaluronic acid is hygroscopic and absorbs water extensively, thus creating volume.4 Treatment with HA fillers is popular, as they are biocompatible and have a low potential for allergic reactions. They also are easy to use and reversible.4 The first HA filler to gain FDA approval was Restylane (Galderma  Laboratories, LP). Currently, several HA fillers are approved in the United States, and each product differs from the others in polymer chain length, degree of HA concentration, particle size, gel consistency, gel hardness, gel viscosity, and degree of water solubility, as well as amount and degree of cross-linking. Cross-linking is essential to avoid enzymatic degradation by endogenous hyaluronidase when injected into the skin and thus to prolong the product’s half-life.5 Cross-linkers used to manufacture HA fillers include 1,4-butanediol diglycidyl ether and divinyl sulfone. More concentrated products with a greater degree of cross-linking provide increased longevity, but they are associated with a higher risk for inflammation and nodule formation. The elastic modulus (G′) is a measure of the firmness of dermal fillers, describing their resistance to deformation. Materials with a higher G′ are stiffer and are meant for deeper injections. Hyaluronic acid fillers can be further classified as biphasic or monophasic. Biphasic fillers (eg, Restylane, Perlane [Galderma Laboratories, LP]) contain a range of microsphere sizes, while monophasic fillers (eg, Juvéderm [Allergan, Inc], Belotero Balance [Merz North America, Inc]) contain homogeneous microspheres. Although randomized clinical trials have reported comparable efficacy and durability of biphasic and monophasic fillers when used to treat the nasolabial folds,6-8 monophasic HA fillers are more cohesive and may not migrate as much following injection.

Restylane Family

Restylane was the first FDA-approved HA filler, gaining its approval in 2003. Restylane is a nonanimal stabilized HA (NASHA) that is produced from the fermentation of equine streptococci. It is cross-linked with 1,4-butanediol diglycidyl ether with a 1% degree of cross-linking. Restylane has an HA concentration of 20 mg/mL. The particle size range of Restylane and Restylane-L is 330 to 430 mm. Restylane (and also Perlane) get passed through sizing screens via sieves and are quantified by their size. The longevity of HA fillers is approximately 6 months; however, various factors affect the product’s longevity, such as the degree of cross-linking, treatment area, and the patient’s metabolism. Restylane-L, which was FDA approved in 2012, is a newer product with 0.3% lidocaine incorporated into the syringe itself. It was the first product from the Restylane range to be approved for lip augmentation. The addition of lidocaine (designated by the L in the product name) does not affect the longevity of a filler.9

The newest FDA-approved HA filler was Restylane Silk (approved in 2014), which has been specifically designed for lip augmentation and correction of perioral rhytides. To avoid postprocedural swelling, it generally is recommended that Restylane Silk be injected slowly. If required, a short course of oral prednisone may be administered after the procedure to treat any edema. Restylane Silk is less viscous than Restylane and requires less pressure to inject. Therefore, it is more suited for treatment of fine perioral lines, as it flows more easily. Because it contains 0.3% lidocaine, discomfort usually is minimal, with treatment lasting approximately 30 to 60 minutes. In the author’s experience (G.G.), Restylane Silk provides a softer correction, though one has to be careful to inject slowly to avoid postinjection swelling. Restylane Silk also may be suitable for neck rejuvenation (off label), but several treatment sessions usually are required. Patients should be warned that they are likely to experience ecchymoses. In our experience, the effects of Restylane Silk injections last approximately 6 to 9 months.

 

 

Juvéderm Family

The first Juvéderm product was approved by the FDA in 2006. Juvéderm is a bacterium-derived NASHA. Injectable gel formulations of Juvéderm, including Juvéderm Ultra and Juvéderm Ultra Plus, are FDA approved for the correction of moderate to severe facial wrinkles and folds. The first products in the Juvéderm line were produced using a technology called Hylacross technology, with cohesive molecules of cross-linked HA. In contrast to the sizing technology used by Restylane and Perlane, the Hylacross technology does not break up the cross-linked HA by passing the product through sizing screens via sieves, but instead produces monophasic gels. These Juvéderm products have a high concentration of cross-linked HAs, which accounts for their longevity, and they are soft and easy to use.

Juvéderm Voluma XC was FDA approved in 2013. It is a 20-mg/mL, smooth, highly cohesive, viscous HA, gel that is manufactured using Vycross technology, a combination of low- and high-molecular-weight HA, and it is the only HA filler that is indicated for deep injection for cheek augmentation,10 as it creates a lift due to its higher G′ and a low swelling capacity, with results lasting up to 2 years. The mean volume administered over the initial 4-week period of one study was 5.1 mL.11

Belotero Balance

Belotero Balance was approved by the FDA in 2011 for the correction of moderate to severe facial wrinkles and folds (eg, nasolabial folds).12 Belotero Balance is an HA filler with a cohesive polydensified matrix technology and low elasticity and viscosity. It has the lowest G′ of the currently available dermal fillers12 and therefore is associated with increased injection precision. Belotero Balance is ideal for superficial injections,13 such as forehead lines, vermilion border, tear trough, atrophic scars, and neck lines (off label). Some clinicians reconstitute Belotero Balance with lidocaine (off label) to provide a more pain-free procedure. In our experience, results typically last at least 6 to 8 months.

Complications

Hyaluronic acid fillers share the same adverse events across the product lines. The most common reactions include erythema, swelling, and bruising, which often are unavoidable and may be considered expected effects. Less-frequent events include contour irregularities; product migration; bluish discoloration known as the Tyndall effect, which is more likely to occur with superficial injections; nodules; infection at the injection site; scarring; and vascular occlusion, potentially leading to blindness.14 These more severe complications often can be avoided. Appropriate skin preparation and a sterile technique are critical in preventing infections, while deep placement of filler material reduces the risk for Tyndall effect, nodules, and scarring. Skin necrosis occurs by external compression of the blood supply by the product or occlusion via direct injection into a vessel. Aspirating prior to injection, administering lower volumes, and tenting the skin to inject more superficially can reduce the risk for skin necrosis. Every clinician needs to be able to rapidly recognize the signs of necrosis and to administer urgent therapy, such as the application of warm gauze and nitroglycerin paste, tapping the area to facilitate vasodilatation, and injecting hyaluronidase when required.

On the Horizon

Other dermal fillers that may gain FDA approval in the next few years include Teosyal (Laboratories  Teoxane Geneva),6 a new range of monophasic NASHA products that provide high viscosity and elasticity with results lasting 6 to 9 months, and potentially Juvéderm Volbella, a smooth, nonparticle, viscous HA gel developed specifically for the lip area with results lasting up to 1 year.15

Conclusion

Over the last decade, the popularity of dermal fillers has steadily increased, and fillers have become a cornerstone of aesthetic medicine. The increased number of available products necessitates thorough knowledge by the treating physician to ensure optimal outcomes. There is no universal filler that can achieve ideal outcomes in all anatomic sites or in all patients. Often a combination approach may be ideal, such as the use of a product with a higher G′ for re-volumization, followed by a filler with a lower G′ for superficial injection. Some patients may also benefit from a combination of both dermal fillers and neurotoxin injections, either on the same day or at separate visits, which may increase the longevity of the filler.

References

1. The American Society for Aesthetic Plastic Surgery reports Americans spent more than 12 billion in 2014; procedures for men up 43% over five year period [news release]. New York, NY: American Society for Aesthetic Plastic Surgery; March 11, 2015. http://www.surgery.org/media/news-releases/the-american-society-for-aesthetic-plastic-surgery-reports-americans-spent-more-than-12-billion-in-2014--pro. Accessed July 7, 2015.

2. Fitzgerald R, Rubin AG. Filler placement and the fat compartments. Dermatol Clin. 2014;32:37-50.

3. Cowman MK, Matsuoka S. Experimental approaches to hyaluronan structure. Carbohydr Res. 2005;340:791-809.

4. Lee A, Grummer SE, Kriegel D, et al. Hyaluronidase. Dermatol Surg. 2010;36:1071-1077.

5. Kablik J, Monheit GD, Yu L, et al. Comparative physical properties of hyaluronic acid dermal fillers. Dermatol Surg. 2009;35(suppl 1):302-312.

6. Nast A, Reytan N, Hartmann V, et al. Efficacy and durability of two hyaluronic acid-based fillers in the correction of nasolabial folds: results of a prospective, randomized, double-blind, actively controlled clinical pilot study. Dermatol Surg. 2011;37:768-775.

7. Ascher B, Bayerl C, Brun P, et al. Efficacy and safety of a new hyaluronic acid dermal filler in the treatment of severe nasolabial lines: 6-month interim results of a randomized, evaluator-blinded, intra-individual comparison study. J Cosmet Dermatol. 2011;10:94-98.

8. Rzany B, Bayerl C, Bodokh I, et al. Efficacy and safety of a new hyaluronic acid dermal filler in the treatment of moderate nasolabial folds: 6-month interim results of a randomized, evaluator-blinded, intra-individual comparison study. J Cosmet Laser Ther. 2011;13:107-112.

9. Lupo MP, Swetman G, Waller W. The effect of lidocaine when mixed with large gel particle hyaluronic acid filler tolerability and longevity: a six-month trial. J Drugs Dermatol. 2010;9:1097-1100.

10. Ho D, Jagdeo J. Biological properties of a new volumizing hyaluronic acid filler: a systematic review. J Drugs Dermatol. 2015;14:50-54.

11. Callan P, Goodman GJ, Carlisle I, et al. Efficacy and safety of a hyaluronic acid filler in subjects treated for correction of midface volume deficiency: a 24 month study. Clin Cosmet Investig Dermatol. 2013;6:81-89.

12. Hevia O, Cohen BH, Howell DJ. Safety and efficacy of a cohesive polydensified matrix hyaluronic acid for the correction of infraorbital hollow: an observational study with results at 40 weeks. J Drugs Dermatol. 2014;13:1030-1036.

13. Lorenc ZP, Fagien S, Flynn TC, et al. Clinical application and assessment of Belotero: a roundtable discussion. Plast Reconstr Surg. 2013;132(4, suppl 2):69S-76S.

14. Carruthers JD, Fagien S, Rohrich RJ, et al. Blindness caused by cosmetic filler injection: a review of cause and therapy. Plast Reconstr Surg. 2014;134:1197-1201.

15. Eccleston D, Murphy DK. Juvéderm(®) Volbella™ in the perioral area: a 12-month prospective, multicenter, open-label study. Clin Cosmet Investig Dermatol. 2012;5:167-172.

References

1. The American Society for Aesthetic Plastic Surgery reports Americans spent more than 12 billion in 2014; procedures for men up 43% over five year period [news release]. New York, NY: American Society for Aesthetic Plastic Surgery; March 11, 2015. http://www.surgery.org/media/news-releases/the-american-society-for-aesthetic-plastic-surgery-reports-americans-spent-more-than-12-billion-in-2014--pro. Accessed July 7, 2015.

2. Fitzgerald R, Rubin AG. Filler placement and the fat compartments. Dermatol Clin. 2014;32:37-50.

3. Cowman MK, Matsuoka S. Experimental approaches to hyaluronan structure. Carbohydr Res. 2005;340:791-809.

4. Lee A, Grummer SE, Kriegel D, et al. Hyaluronidase. Dermatol Surg. 2010;36:1071-1077.

5. Kablik J, Monheit GD, Yu L, et al. Comparative physical properties of hyaluronic acid dermal fillers. Dermatol Surg. 2009;35(suppl 1):302-312.

6. Nast A, Reytan N, Hartmann V, et al. Efficacy and durability of two hyaluronic acid-based fillers in the correction of nasolabial folds: results of a prospective, randomized, double-blind, actively controlled clinical pilot study. Dermatol Surg. 2011;37:768-775.

7. Ascher B, Bayerl C, Brun P, et al. Efficacy and safety of a new hyaluronic acid dermal filler in the treatment of severe nasolabial lines: 6-month interim results of a randomized, evaluator-blinded, intra-individual comparison study. J Cosmet Dermatol. 2011;10:94-98.

8. Rzany B, Bayerl C, Bodokh I, et al. Efficacy and safety of a new hyaluronic acid dermal filler in the treatment of moderate nasolabial folds: 6-month interim results of a randomized, evaluator-blinded, intra-individual comparison study. J Cosmet Laser Ther. 2011;13:107-112.

9. Lupo MP, Swetman G, Waller W. The effect of lidocaine when mixed with large gel particle hyaluronic acid filler tolerability and longevity: a six-month trial. J Drugs Dermatol. 2010;9:1097-1100.

10. Ho D, Jagdeo J. Biological properties of a new volumizing hyaluronic acid filler: a systematic review. J Drugs Dermatol. 2015;14:50-54.

11. Callan P, Goodman GJ, Carlisle I, et al. Efficacy and safety of a hyaluronic acid filler in subjects treated for correction of midface volume deficiency: a 24 month study. Clin Cosmet Investig Dermatol. 2013;6:81-89.

12. Hevia O, Cohen BH, Howell DJ. Safety and efficacy of a cohesive polydensified matrix hyaluronic acid for the correction of infraorbital hollow: an observational study with results at 40 weeks. J Drugs Dermatol. 2014;13:1030-1036.

13. Lorenc ZP, Fagien S, Flynn TC, et al. Clinical application and assessment of Belotero: a roundtable discussion. Plast Reconstr Surg. 2013;132(4, suppl 2):69S-76S.

14. Carruthers JD, Fagien S, Rohrich RJ, et al. Blindness caused by cosmetic filler injection: a review of cause and therapy. Plast Reconstr Surg. 2014;134:1197-1201.

15. Eccleston D, Murphy DK. Juvéderm(®) Volbella™ in the perioral area: a 12-month prospective, multicenter, open-label study. Clin Cosmet Investig Dermatol. 2012;5:167-172.

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Hyaluronic Acid Fillers, Facial Rejuvenation, Plastic Surgery, nonsurgical procedures, botulinum toxin, hyaluronic acid, HA, hair removal, chemical peels, microdermabrasion, cosmetic dermatology, antiaging
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     Practice Points

  • ­Restylane Silk is useful for the treatment of fine perioral lines.
  • ­Juvéderm Voluma XC is a newer product in the Juvéderm range and is indicated for cheek augmentation.
  • Belotero Balance has the lowest G′ of the currently available dermal fillers and allows greater precision.
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New Systemic Therapies for Psoriasis

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New Systemic Therapies for Psoriasis

Psoriasis is a common chronic inflammatory skin disease affecting 1% to 8% of the world population, depending on the country.1 Psoriasis can greatly impact quality of life in affected individuals, even in those with limited body surface involvement.2 Studies have demonstrated a high degree of psychological distress associated with psoriasis, leading to depression and poor self-esteem.3

Over the last decade, our improved understanding of the autoimmune inflammatory pathways and the associated changing concepts in psoriasis pathogenesis have led to the development of biological drugs targeting specific components of effector immune mechanisms, and these biological drugs have revolutionized the treatment of psoriasis.4 Although response rates of these biological agents are greater compared to those of conventional systemic drugs,5 current biological drugs fail to demonstrate efficacy in some patients or lose their efficacy over time. In addition to the high costs associated with these drugs, these limitations have driven a continued search for alternative therapies.

Helper T cells (TH17) and the proinflammatory cytokine IL-17 have been shown to play a key role in the pathophysiology of psoriasis, bridging innate and adaptive immune responses. IL-17 is involved in the modulation of proinflammatory cytokines, hematopoietic growth factors, antimicrobial peptides, and chemokines. Increased TH17 activity and high levels of IL-17 have been found in psoriatic plaques, and increased levels of TH17 are found in the plasma of psoriasis patients.6 Increased IL-17 induces neutrophilia, inflammation, and angiogenesis.7 Other cytokines that are highly upregulated in involved skin are tumor necrosis factor a (TNF-α), IL-23, IL-22, and IL-21.8 IL-23 is involved in regulating TH17 cells and is a potent activator of keratinocyte proliferation.9 Blockade of IL-12/23 causes downregulation of TH17 and TH22 cell responses.10 As IL-17 has a key role in protecting skin and mucous membranes from bacterial and fungal infections, IL-17 inhibition can potentially interfere with the inflammatory cascade. However, available data suggest that sufficient residual IL-17 activity remains to maintain immunity against infections.11

Currently approved biological agents for psoriasis target proinflammatory cytokines such as TNF-α, or the p40 subunit of IL-12 and IL-23. A number of novel targeted therapies including biologics as well as small molecule inhibitors targeting various cytokines and molecules involved in the pathogenesis of psoriasis are currently in different stages of development (Table). These drugs include 3 IL-17 inhibitors (secukinumab, ixekizumab, and brodalumab); 2 IL-23 blockers (tildrakizumab and guselkumab); and small molecule inhibitors that target the kinase pathway including apremilast (a phosphodiesterase 4 [PDE4] inhibitor), as well as tofacitinib, baricitinib, and ruxolitinib (Janus kinase [Jak] inhibitors). Small molecule inhibitors can be administered orally and are less expensive to produce than biological agents. This article reviews available data on these new systemic agents in the pipeline.

Novel Biologics

Secukinumab

Secukinumab is a fully human monoclonal IgG1k antibody that selectively binds and neutralizes IL-17A.12 It is the first of the IL-17 antibodies to receive approval for the treatment of moderate to severe psoriasis. In 2 phase 3, double-blind, 52-week trials—ERASURE (Efficacy of Response and Safety of Two Fixed Secukinumab Regimens in Psoriasis) and FIXTURE (Full Year Investigative Examination of Secukinumab vs Etanercept Using Two Dosing Regimens to Determine Efficacy in Psoriasis)—participants were randomly assigned to receive subcutaneous secukinumab at doses of 300 mg (n=245 and n=327, respectively) or 150 mg (n=245 and n=327, respectively) once weekly for 5 weeks then every 4 weeks, or placebo (n=248 and n=326, respectively); in the FIXTURE study only, an etanercept group (n=326) was given a 50-mg dose twice weekly for 12 weeks then once weekly.13

In the ERASURE study, the proportion of participants showing a reduction of 75% or more in psoriasis area and severity index (PASI) score from baseline to week 12 was 81.6% with secukinumab 300 mg, 71.6% with secukinumab 150 mg, and 4.5% with placebo.13 Secondary end point results demonstrated the proportion of participants showing a 90% reduction in PASI score was 59.2% with secukinumab 300 mg and 39.1% with secukinumab 150 mg, which were both superior to placebo (1.2%). The proportion of participants who met the criteria for 100% reduction in PASI score at week 12 also was greater with each secukinumab dose than with placebo.13

In the FIXTURE study, the proportion of participants showing a reduction of 75% or more from baseline in PASI score at week 12 was 77.1% with secukinumab 300 mg, 67.0% with secukinumab 150 mg, 44.0% with etanercept, and 4.9% with placebo.13 Secondary end point results demonstrated the proportion of participants showing a 90% reduction in PASI score was 54.2% with secukinumab 300 mg, 41.9% with secukinumab 150 mg, 20.7% with etanercept, and 1.5% with placebo. The speed of response, which was assessed as the median time to a 50% reduction in mean PASI score from baseline, was significantly shorter with both doses of secukinumab (3.0 weeks and 3.9 weeks, respectively) than with etanercept (7.0 weeks)(P<.001 for both).13

 

 

In the FIXTURE study, incidences of adverse events (AEs) were similar in the secukinumab and etanercept groups during both the induction period and the entire treatment period.13 The most common AEs in the secukinumab groups were nasopharyngitis, headache, and diarrhea. The rates of infections or infestations during the induction period were 26.7% with secukinumab 300 mg, 30.9% with secukinumab 150 mg, 24.5% with etanercept, and 19.3% with placebo. Candidal infections were more common with secukinumab than with etanercept during the entire treatment period (4.7% and 2.3% of participants in the secukinumab 300 mg and 150 mg groups, respectively, reported mild or moderate candidal infections). None of these infections resulted in chronic mucocutaneous candidiasis or discontinuation of the study drug and all resolved on their own or with standard therapy. Candidal infection was reported in 1.2% of participants in the etanercept group. Responses at week 12 were sustained in the majority of participants through week 52 with continued secukinumab therapy every 4 weeks. Grade 3 neutropenia occurred in 1.0% of secukinumab-treated participants and in none of the participants in the etanercept group. There were no apparent dose-related differences between the secukinumab groups with respect to AEs, with the exception of mild and moderate candidal infections.13

These efficacy data are impressive and no specific serious safety concerns have been identified to date. However, IL-17A plays a key role in host defense, particularly in mucocutaneous immunity against Candida albicans,14 as well as in hematopoiesis through stimulation of granulopoiesis and neutrophil trafficking,15 and thus we need to remain watchful with regards to Candida albicans infections and neutropenia.

Ixekizumab

Ixekizumab is a humanized IgG4 anti–IL-17A monoclonal antibody. In a phase 2, double-blind, placebo-controlled trial, 142 participants with chronic moderate to severe plaque psoriasis were randomly assigned to receive 150-mg (n=28), 75-mg (n=29), 25-mg (n=30), or 10-mg (n=28) subcutaneous injections of ixekizumab or placebo (n=27) at weeks 0, 2, 4, 8, 12, and 16.16 At 12 weeks, the percentage of participants who achieved a 75% reduction in PASI score from baseline was significantly greater with ixekizumab (82.1% with 150-mg dose, 82.8% with 75-mg dose, 76.7% with 25-mg dose) than with placebo (7.7%)(P<.001 for each comparison), except with the 10-mg dose. Similarly, a greater percentage of participants in the same ixekizumab groups achieved a 90% reduction (71.4% with 150-mg dose, 58.6% with 75-mg dose, 50.0% with 25-mg dose) and a 100% reduction (39.3% with 150-mg dose, 37.9% with 75-mg dose) in PASI score compared to placebo (0%)(P<.001 for each comparison). Significant reductions in PASI scores were evident as early as week 1 in the 150-mg and 75-mg groups, and these reductions were sustained for 20 weeks (P<.05).16 Phase 3 studies of ixekizumab currently are underway.

Brodalumab

The third IL-17 blocker in the pipeline is brodalumab, a human monoclonal antibody against IL-17RA, which blocks signaling of IL-17A and IL-17F as well as the IL-17A/F heterodimer, all of which are involved in the inflammatory process of psoriasis. Brodalumab was evaluated in a phase 2, double-blind, placebo-controlled, dose-ranging study of 198 participants who were randomized to receive 70 mg (n=39), 140 mg (n=39), 210 mg (n=40), or 280 mg (n=42) of brodalumab or placebo (n=38).17 At week 12, improvements of at least 75% and at least 90% in PASI score were achieved by 77% and 72%, respectively, in the 140-mg group, and 82% and 75%, respectively, in the 210-mg group compared to 0% of the placebo group (P<.001 for all comparisons). One hundred percent improvement in PASI was achieved by 38% of participants in the 140-mg group and 62% in the 210-mg group. No participants in the placebo group demonstrated improvement of 75% or higher. The most common AEs were nasopharyngitis, upper respiratory tract infection, arthralgia, and injection-site erythema. Serious AEs reported during the study included renal colic (1 participant), ec-topic pregnancy (1 participant), and grade 3 asymptomatic neutropenia (2 participants). Both cases of neutropenia were noted at the first assessment after brodalumab initiation (week 2) and resolved when the study drug was withheld.17

Results for this new IL-17 blocker are encouraging, but phase 3 data of brodalumab will need to be awaited.

Tildrakizumab

Tildrakizumab is a humanized IgG1 monoclonal antibody that blocks the p19 subunit of IL-23. In a randomized, double-blind, phase 2b trial, 355 adults with moderate to severe psoriasis were randomized to receive subcutaneous injections of tildrakizumab (5 mg, 25 mg, 100 mg, or 200 mg) or placebo.18 In part 1 of the study, injections were administered at weeks 0 and 4. Part 2 of the study started at week 16. In part 2, responders with a 75% improvement in PASI score in the 5- and 25-mg groups continued their dose, while responders in the 100- or 200-mg groups were randomized again to continue the same dose or a reduced dose (100 mg to 25 mg; 200 mg to 100 mg) every 12 weeks from weeks 16 to 52. Those in the placebo group received tildrakizumab 25 mg every 12 weeks in part 2. The primary end point was the mean change in PASI score from baseline to week 16, which was significantly greater in all tildrakizumab groups than in the placebo group (P<.001 for all comparisons). Improvements of 75% in PASI score were achieved by 74% in the 200-mg group, 66% in the 100-mg group, 64% in the 25-mg group, and 33% in the 5-mg group. In contrast, 4.9% in the placebo group achieved an improvement of 75%. At week 52, no loss of efficacy was seen in those participants who had achieved 75% improvement in PASI score at week 16 and had continued their prior doses. The rates of AEs seen in the tildrakizumab groups were 60% to 71% compared to 69% in the placebo group. The most common AE was nasopharyngitis, occurring in 12% to 20% of participants in each group. Serious AEs were uncommon.18 Phase 3 studies are currently underway.19

 

 

Guselkumab

Guselkumab is a human IgG1 monoclonal antibody in clinical development that specifically blocks the p19 subunit of IL-23. In a double-blind, placebo-controlled, phase 1 study, 24 participants with moderate to severe plaque psoriasis were randomized to receive a single 10-mg (n=5), 30-mg (n=5), 100-mg (n=5), or 300-mg (n=5) dose of guselkumab or placebo (n=4).20 At week 12, 50% in the 10-mg group, 60% in both the 30- and 100-mg groups, and 100% in the 300-mg group showed 75% improvement in PASI score versus 0% in the placebo group. Improvements in PASI scores were generally maintained through week 24. The rates of AEs were 65% (13/20) in the combined guselkumab group and 50% (2/4) in the placebo group.20

Small Molecule Inhibitors

In contrast to biologics, which mainly target soluble cytokine or cellular receptors, small molecule inhibitors target enzymes within signaling pathways. Small molecule inhibitors have some advantages over biologics in that they are relatively inexpensive to produce and can be administered orally; thus, they may be preferred by some patients over injectable drugs. There are several agents that are undergoing clinical trials in psoriasis, including PDE4 inhibitors and Jak inhibitors.

Apremilast

Apremilast is an oral small molecule PDE4 inhibitor that was approved by the US Food and Drug Administration in March 2014 for the treatment of adult patients with active psoriatic arthritis; an indication for moderate to severe plaque psoriasis was approved in September 2014.21 Phosphodiesterase 4 is a cyclic adenosine monophosphate–specific phosphodiesterase inhibitor, which is dominant in inflammatory cells. Inhibition of PDE4 increases intracellular cyclic adenosine monophosphate levels, thus downregulating proinflammatory cytokines such as TNF-α, IFN-γ, IL-2, IL-12, and IL-23, and increasing the production of anti-inflammatory cytokines such as IL-10.22

Phase 2 and phase 3 studies have demonstrated the clinical efficacy of apremilast in the treatment of patients with moderate to severe plaque psoriasis. In a 16-week randomized, placebo-controlled, phase 3 trial (ESTEEM 2), 408 participants were randomized to receive oral apremilast 30 mg twice daily (n=275) or placebo (n=138).23 Improvement of 75% in PASI score was achieved by 29% of participants in the apremilast group at week 16. The most common AEs were diarrhea (16%) and nausea (18%), which were predominantly mild, occurring most commonly in the first week and resolving within 1 month. No cases of severe diarrhea or severe nausea were reported. Apremilast had no apparent effect on the results of hematological or serum chemistry tests.23 Although the US Food and Drug Administration warns of a possible link between apremilast and depression,24 data are mostly related to roflumilast, another PDE4 inhibitor. Studies in patients with chronic obstructive pulmonary disease have noted increased cases of depression (1.21% vs 0.82%) and suicidal ideation/attempt (0.03% vs 0.02%) in patients treated with roflumilast versus placebo.25

Jak Inhibitors

Janus kinases are a family of intracellular tyrosine kinases that connect several cytokine receptors to the signal transducer and activator of transcription pathways.26 There are 4 Jak family members: Jak1, Jak2, Jak3, and tyrosine kinase 2. Janus kinases 1 and 2 have roles in interferon signaling, while Jak3 transduces signals from IL-2, IL-7, IL-15, and IL-21, which are T-cell growth and survival factors.

Tofacitinib is a novel oral signal transduction molecule that blocks the Jak3 pathway. A phase 2b, 12-week, dose-ranging study was conducted to assess the efficacy and safety of 3 twice-daily regimens of tofacitinib versus placebo in patients with moderate to severe chronic plaque psoriasis.27 One hundred and ninety-seven participants were randomized to receive oral tofacitinib (2 mg, 5 mg, or 15 mg; n=49 each) or placebo (n=50) twice daily for 12 weeks with a 4-week follow-up period. The primary end point was the proportion of participants achieving at least a 75% reduction in PASI score at week 12 (25.0% with 2 mg, 40.8% with 5 mg, 66.7% with 15 mg, 2.0% with placebo). Similarly, a higher proportion of participants achieving 90% reduction in PASI score was seen at weeks 8 and 12 in all tofacitinib-treated participants versus placebo. The most common AEs were upper respiratory tract infection, sinusitis, nasopharyngitis, and headache. A number of changes in laboratory parameters occurred in the tofacitinib groups. Mild dose-related decreases in hemoglobin were noted at week 12 for all tofacitinib groups, and a small increase (mean, 0.04 mg/dL) in serum creatinine levels was observed in the 15-mg group. Decreases in neutrophil counts were observed with higher doses of tofacitinib, with the maximum mean decrease of 0.9×103/mm3 from baseline observed in the 15-mg group at week 4. After weeks 4 through 8, mean neutrophil counts began to return to baseline levels. Dose-related increases in total cholesterol, high-density lipoprotein cholesterol, and low-density lipoprotein cholesterol were observed by week 2 and remained at this level through week 12; mean lipid levels decreased to baseline levels after cessation of active treatment. One participant in the 15-mg group developed an elevated alanine aminotransferase level that was more than 2.5 times the highest normal limit. Three participants experienced 5 serious AEs.27 These early results show that tofacitinib can be a safe and effective treatment in patients with psoriasis, but further data from phase 3 studies will need to be awaited.

 

 

Another Jak inhibitor under investigationfor the treatment of psoriasis is ruxolitinib, an inhibitor of Jak1 and Jak2, which has been primarily studied as a topical agent for milder cases of the disease.28

Conclusion

Many new drugs are currently on the horizon and will increase our armamentarium for treating psoriasis. Some of these agents promise greater levels of efficacy than currently used therapies. Although this review focuses on systemic agents, there also are a number of topical formulations in the pipeline. These new agents will certainly increase our options when choosing the most suitable treatment for a patient with psoriasis, but safety will remain a primary concern, and time and experience will tell whether efficacy outweighs any potential side effects.

References

 

1. Parisi R, Symmons DP, Griffiths CE, et al. Global epidemiology of psoriasis: a systematic review of incidence and prevalence. J Invest Dermatol. 2013;133:377-385.

2. Rapp SR, Feldman SR, Exum ML, et al. Psoriasis causes as much disability as other major medical diseases. J Am Acad Dermatol. 1999;41(3 pt 1):401-407.

3. Shah R, Bewley A. Psoriasis: ‘the badge of shame.’ a case report of a psychological intervention to reduce and potentially clear chronic skin disease. Clin Exp Dermatol. 2014;39:600-603.

4. Vincent FB, Morand EF, Murphy K, et al. Antidrug antibodies (ADAb) to tumour necrosis factor (TNF)-specific neutralising agents in chronic inflammatory diseases: a real issue, a clinical perspective. Ann Rheum Dis. 2013;72:165-178.

5. Chi CC, Wang SH. Efficacy and cost-efficacy of biologic therapies for moderate to severe psoriasis: a meta-analysis and cost-efficacy analysis using the intention-to-treat principle. Biomed Res Int. 2014;2014:862851.

6. Kagami S, Rizzo HL, Lee JJ, et al. Circulating Th17, Th22, and Th1 cells are increased in psoriasis. J Invest Dermatol. 2010;130:1373-1383.

7. Leonardi CL, Gordon KB. New and emerging therapies in psoriasis. Semin Cutan Med Surg. 2014;33(2, suppl 2):S37-S41.

8. Lowes MA, Kikuchi T, Fuentes-Duculan J, et al. Psoriasis vulgaris lesions contain discrete populations of Th1 and Th17 T cells. J Invest Dermatol. 2008;128:1207-1211.

9. Nickoloff BJ, Qin JZ, Nestle FO. Immunopathogenesis of psoriasis. Clin Rev Allergy Immunol. 2007;33:45-56.

10. Fitch E, Harper E, Skorcheva I, et al. Pathophysiology of psoriasis: recent advances on IL-23 and Th17 cytokines. Curr Rheumatol Rep. 2007;9:461-467.

11. Adami S, Cavani A, Rossi F, et al. The role of interleukin-17A in psoriatic disease. BioDrugs. 2014;28:487-497.

12. Hueber W, Patel DD, Dryja T, et al. Effects of AIN457, a fully human antibody to interleukin-17A, on psoriasis, rheumatoid arthritis, and uveitis. Sci Transl Med. 2010;2:52ra72.

13. Langley RG, Elewski BE, Lebwohl M, et al. Secukinumab in plaque psoriasis—results of two phase 3 trials. N Engl J Med. 2014;371:326-338.

14. Puel A, Cypowyj S, Bustamante J, et al. Chronic mucocutaneous candidiasis in humans with inborn errors of interleukin-17 immunity. Science. 2011;332:65-68.

15. Krstic A, Mojsilovic S, Jovcic G, et al. The potential of interleukin-17 to mediate hematopoietic response. Immunol Res. 2012;52:34-41.

16. Leonardi C, Matheson R, Zachariae C, et al. Anti-interleukin-17 monoclonal antibody ixekizumab in chronic plaque psoriasis. N Engl J Med. 2012;366:1190-1199.

17. Papp KA, Leonardi C, Menter A, et al. Brodalumab, an anti-interleukin-17-receptor antibody for psoriasis. N Engl J Med. 2012;366:1181-1189.

18. Langley RGB, Thaci D, Papp KA, et al. MK-3222, an anti–IL-23p19 humanized monoclonal antibody, provides significant improvement in psoriasis over 52 weeks of treatment that is maintained after discontinuation of dosing. Poster presented at: 73rd Annual Meeting of the American Academy of Dermatology; March 21-25, 2014; Denver, CO. Poster 8056.

19. Tausend W, Downing C, Tyring S. Systematic review of interleukin-12, interleukin-17, and interleukin-23 pathway inhibitors for the treatment of moderate-to-severe chronic plaque psoriasis: ustekinumab, briakinumab, tildrakizumab, guselkumab, secukinumab, ixekizumab, and brodalumab. J Cutan Med Surg. 2014;18:156-169.

20. Sofen H, Smith S, Matheson RT, et al. Guselkumab (an IL-23-specific mAb) demonstrates clinical and molecular response in patients with moderate-to-severe psoriasis. J Allergy Clin Immunol. 2014;133:1032-1040.

21. Schafer PH, Parton A, Capone L, et al. Apremilast is a selective PDE4 inhibitor with regulatory effects on innate immunity. Cell Signal. 2014;26:2016-2029.

22. van de Kerkhof PC. Apremilast: a step forward in the treatment of psoriasis? Lancet. 2012;380:708-709.

23. Paul C, Crowley J, Cather J, et al. Apremilast, an oral phosphodiesterase 4 inhibitor, in patients with moderate to severe psoriasis: 16-week results of a phase 3, randomized, controlled trial (ESTEEM 2). Poster presented at: 73rd Annual Meeting of the American Academy of Dermatology; March 21-25, 2014; Denver, CO. Poster 8412.

24. Otezla [product insert]. Summit, NJ: Celgene Corporation; 2014.

25. Rabe KF. Update on roflumilast, a phosphodiesterase 4 inhibitor for the treatment of chronic obstructive pulmonary disease. Br J Pharmacol. 2011;163:53-67.

26. Palanivel JA, Macbeth AE, Chetty NC, et al. An insight into JAK-STAT signalling in dermatology. Clin Exp Dermatol. 2014;39:513-518.

27. Papp KA, Menter A, Strober B, et al. Efficacy and safety of tofacitinib, an oral Janus kinase inhibitor, in the treatment of psoriasis: a phase 2b randomized placebo-controlled dose-ranging study. Br J Dermatol. 2012;167:668-677.

28. Hsu L, Armstrong AW. JAK inhibitors: treatment efficacy and safety profile in patients with psoriasis. J Immunol Res. 2014;2014:283617.

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Author and Disclosure Information

 

Yasaman Mansouri, MD, MRCP; Gary Goldenberg, MD

From the Department of Dermatology, Icahn School of Medicine at Mount Sinai, New York, New York.

Dr. Mansouri reports no conflict of interest, but her contribution was supported by the Geoffrey Dowling Fellowship, a grant from the British Association of Dermatologists (United Kingdom). Dr. Goldenberg is a consultant and speaker for AbbVie Inc, Celgene Corporation, and Novartis Corporation. He also is a consultant for Amgen Inc, Janssen Biotech Inc, and Pfizer Inc. 

Correspondence: Gary Goldenberg, MD, 5 E 98th St, 5th Floor, New York, NY 10029-6574 ([email protected]).

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155-160
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Psoriasis, chronic inflammatory skin disease, Tildrakizumab, Guselkumab, Ixekizumab, Secukinumab, Jak Inhibitors, Apremilast, Tofacitinib, biological agents, biologics, small molecule inhibitors
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Author and Disclosure Information

 

Yasaman Mansouri, MD, MRCP; Gary Goldenberg, MD

From the Department of Dermatology, Icahn School of Medicine at Mount Sinai, New York, New York.

Dr. Mansouri reports no conflict of interest, but her contribution was supported by the Geoffrey Dowling Fellowship, a grant from the British Association of Dermatologists (United Kingdom). Dr. Goldenberg is a consultant and speaker for AbbVie Inc, Celgene Corporation, and Novartis Corporation. He also is a consultant for Amgen Inc, Janssen Biotech Inc, and Pfizer Inc. 

Correspondence: Gary Goldenberg, MD, 5 E 98th St, 5th Floor, New York, NY 10029-6574 ([email protected]).

Author and Disclosure Information

 

Yasaman Mansouri, MD, MRCP; Gary Goldenberg, MD

From the Department of Dermatology, Icahn School of Medicine at Mount Sinai, New York, New York.

Dr. Mansouri reports no conflict of interest, but her contribution was supported by the Geoffrey Dowling Fellowship, a grant from the British Association of Dermatologists (United Kingdom). Dr. Goldenberg is a consultant and speaker for AbbVie Inc, Celgene Corporation, and Novartis Corporation. He also is a consultant for Amgen Inc, Janssen Biotech Inc, and Pfizer Inc. 

Correspondence: Gary Goldenberg, MD, 5 E 98th St, 5th Floor, New York, NY 10029-6574 ([email protected]).

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Related Articles

Psoriasis is a common chronic inflammatory skin disease affecting 1% to 8% of the world population, depending on the country.1 Psoriasis can greatly impact quality of life in affected individuals, even in those with limited body surface involvement.2 Studies have demonstrated a high degree of psychological distress associated with psoriasis, leading to depression and poor self-esteem.3

Over the last decade, our improved understanding of the autoimmune inflammatory pathways and the associated changing concepts in psoriasis pathogenesis have led to the development of biological drugs targeting specific components of effector immune mechanisms, and these biological drugs have revolutionized the treatment of psoriasis.4 Although response rates of these biological agents are greater compared to those of conventional systemic drugs,5 current biological drugs fail to demonstrate efficacy in some patients or lose their efficacy over time. In addition to the high costs associated with these drugs, these limitations have driven a continued search for alternative therapies.

Helper T cells (TH17) and the proinflammatory cytokine IL-17 have been shown to play a key role in the pathophysiology of psoriasis, bridging innate and adaptive immune responses. IL-17 is involved in the modulation of proinflammatory cytokines, hematopoietic growth factors, antimicrobial peptides, and chemokines. Increased TH17 activity and high levels of IL-17 have been found in psoriatic plaques, and increased levels of TH17 are found in the plasma of psoriasis patients.6 Increased IL-17 induces neutrophilia, inflammation, and angiogenesis.7 Other cytokines that are highly upregulated in involved skin are tumor necrosis factor a (TNF-α), IL-23, IL-22, and IL-21.8 IL-23 is involved in regulating TH17 cells and is a potent activator of keratinocyte proliferation.9 Blockade of IL-12/23 causes downregulation of TH17 and TH22 cell responses.10 As IL-17 has a key role in protecting skin and mucous membranes from bacterial and fungal infections, IL-17 inhibition can potentially interfere with the inflammatory cascade. However, available data suggest that sufficient residual IL-17 activity remains to maintain immunity against infections.11

Currently approved biological agents for psoriasis target proinflammatory cytokines such as TNF-α, or the p40 subunit of IL-12 and IL-23. A number of novel targeted therapies including biologics as well as small molecule inhibitors targeting various cytokines and molecules involved in the pathogenesis of psoriasis are currently in different stages of development (Table). These drugs include 3 IL-17 inhibitors (secukinumab, ixekizumab, and brodalumab); 2 IL-23 blockers (tildrakizumab and guselkumab); and small molecule inhibitors that target the kinase pathway including apremilast (a phosphodiesterase 4 [PDE4] inhibitor), as well as tofacitinib, baricitinib, and ruxolitinib (Janus kinase [Jak] inhibitors). Small molecule inhibitors can be administered orally and are less expensive to produce than biological agents. This article reviews available data on these new systemic agents in the pipeline.

Novel Biologics

Secukinumab

Secukinumab is a fully human monoclonal IgG1k antibody that selectively binds and neutralizes IL-17A.12 It is the first of the IL-17 antibodies to receive approval for the treatment of moderate to severe psoriasis. In 2 phase 3, double-blind, 52-week trials—ERASURE (Efficacy of Response and Safety of Two Fixed Secukinumab Regimens in Psoriasis) and FIXTURE (Full Year Investigative Examination of Secukinumab vs Etanercept Using Two Dosing Regimens to Determine Efficacy in Psoriasis)—participants were randomly assigned to receive subcutaneous secukinumab at doses of 300 mg (n=245 and n=327, respectively) or 150 mg (n=245 and n=327, respectively) once weekly for 5 weeks then every 4 weeks, or placebo (n=248 and n=326, respectively); in the FIXTURE study only, an etanercept group (n=326) was given a 50-mg dose twice weekly for 12 weeks then once weekly.13

In the ERASURE study, the proportion of participants showing a reduction of 75% or more in psoriasis area and severity index (PASI) score from baseline to week 12 was 81.6% with secukinumab 300 mg, 71.6% with secukinumab 150 mg, and 4.5% with placebo.13 Secondary end point results demonstrated the proportion of participants showing a 90% reduction in PASI score was 59.2% with secukinumab 300 mg and 39.1% with secukinumab 150 mg, which were both superior to placebo (1.2%). The proportion of participants who met the criteria for 100% reduction in PASI score at week 12 also was greater with each secukinumab dose than with placebo.13

In the FIXTURE study, the proportion of participants showing a reduction of 75% or more from baseline in PASI score at week 12 was 77.1% with secukinumab 300 mg, 67.0% with secukinumab 150 mg, 44.0% with etanercept, and 4.9% with placebo.13 Secondary end point results demonstrated the proportion of participants showing a 90% reduction in PASI score was 54.2% with secukinumab 300 mg, 41.9% with secukinumab 150 mg, 20.7% with etanercept, and 1.5% with placebo. The speed of response, which was assessed as the median time to a 50% reduction in mean PASI score from baseline, was significantly shorter with both doses of secukinumab (3.0 weeks and 3.9 weeks, respectively) than with etanercept (7.0 weeks)(P<.001 for both).13

 

 

In the FIXTURE study, incidences of adverse events (AEs) were similar in the secukinumab and etanercept groups during both the induction period and the entire treatment period.13 The most common AEs in the secukinumab groups were nasopharyngitis, headache, and diarrhea. The rates of infections or infestations during the induction period were 26.7% with secukinumab 300 mg, 30.9% with secukinumab 150 mg, 24.5% with etanercept, and 19.3% with placebo. Candidal infections were more common with secukinumab than with etanercept during the entire treatment period (4.7% and 2.3% of participants in the secukinumab 300 mg and 150 mg groups, respectively, reported mild or moderate candidal infections). None of these infections resulted in chronic mucocutaneous candidiasis or discontinuation of the study drug and all resolved on their own or with standard therapy. Candidal infection was reported in 1.2% of participants in the etanercept group. Responses at week 12 were sustained in the majority of participants through week 52 with continued secukinumab therapy every 4 weeks. Grade 3 neutropenia occurred in 1.0% of secukinumab-treated participants and in none of the participants in the etanercept group. There were no apparent dose-related differences between the secukinumab groups with respect to AEs, with the exception of mild and moderate candidal infections.13

These efficacy data are impressive and no specific serious safety concerns have been identified to date. However, IL-17A plays a key role in host defense, particularly in mucocutaneous immunity against Candida albicans,14 as well as in hematopoiesis through stimulation of granulopoiesis and neutrophil trafficking,15 and thus we need to remain watchful with regards to Candida albicans infections and neutropenia.

Ixekizumab

Ixekizumab is a humanized IgG4 anti–IL-17A monoclonal antibody. In a phase 2, double-blind, placebo-controlled trial, 142 participants with chronic moderate to severe plaque psoriasis were randomly assigned to receive 150-mg (n=28), 75-mg (n=29), 25-mg (n=30), or 10-mg (n=28) subcutaneous injections of ixekizumab or placebo (n=27) at weeks 0, 2, 4, 8, 12, and 16.16 At 12 weeks, the percentage of participants who achieved a 75% reduction in PASI score from baseline was significantly greater with ixekizumab (82.1% with 150-mg dose, 82.8% with 75-mg dose, 76.7% with 25-mg dose) than with placebo (7.7%)(P<.001 for each comparison), except with the 10-mg dose. Similarly, a greater percentage of participants in the same ixekizumab groups achieved a 90% reduction (71.4% with 150-mg dose, 58.6% with 75-mg dose, 50.0% with 25-mg dose) and a 100% reduction (39.3% with 150-mg dose, 37.9% with 75-mg dose) in PASI score compared to placebo (0%)(P<.001 for each comparison). Significant reductions in PASI scores were evident as early as week 1 in the 150-mg and 75-mg groups, and these reductions were sustained for 20 weeks (P<.05).16 Phase 3 studies of ixekizumab currently are underway.

Brodalumab

The third IL-17 blocker in the pipeline is brodalumab, a human monoclonal antibody against IL-17RA, which blocks signaling of IL-17A and IL-17F as well as the IL-17A/F heterodimer, all of which are involved in the inflammatory process of psoriasis. Brodalumab was evaluated in a phase 2, double-blind, placebo-controlled, dose-ranging study of 198 participants who were randomized to receive 70 mg (n=39), 140 mg (n=39), 210 mg (n=40), or 280 mg (n=42) of brodalumab or placebo (n=38).17 At week 12, improvements of at least 75% and at least 90% in PASI score were achieved by 77% and 72%, respectively, in the 140-mg group, and 82% and 75%, respectively, in the 210-mg group compared to 0% of the placebo group (P<.001 for all comparisons). One hundred percent improvement in PASI was achieved by 38% of participants in the 140-mg group and 62% in the 210-mg group. No participants in the placebo group demonstrated improvement of 75% or higher. The most common AEs were nasopharyngitis, upper respiratory tract infection, arthralgia, and injection-site erythema. Serious AEs reported during the study included renal colic (1 participant), ec-topic pregnancy (1 participant), and grade 3 asymptomatic neutropenia (2 participants). Both cases of neutropenia were noted at the first assessment after brodalumab initiation (week 2) and resolved when the study drug was withheld.17

Results for this new IL-17 blocker are encouraging, but phase 3 data of brodalumab will need to be awaited.

Tildrakizumab

Tildrakizumab is a humanized IgG1 monoclonal antibody that blocks the p19 subunit of IL-23. In a randomized, double-blind, phase 2b trial, 355 adults with moderate to severe psoriasis were randomized to receive subcutaneous injections of tildrakizumab (5 mg, 25 mg, 100 mg, or 200 mg) or placebo.18 In part 1 of the study, injections were administered at weeks 0 and 4. Part 2 of the study started at week 16. In part 2, responders with a 75% improvement in PASI score in the 5- and 25-mg groups continued their dose, while responders in the 100- or 200-mg groups were randomized again to continue the same dose or a reduced dose (100 mg to 25 mg; 200 mg to 100 mg) every 12 weeks from weeks 16 to 52. Those in the placebo group received tildrakizumab 25 mg every 12 weeks in part 2. The primary end point was the mean change in PASI score from baseline to week 16, which was significantly greater in all tildrakizumab groups than in the placebo group (P<.001 for all comparisons). Improvements of 75% in PASI score were achieved by 74% in the 200-mg group, 66% in the 100-mg group, 64% in the 25-mg group, and 33% in the 5-mg group. In contrast, 4.9% in the placebo group achieved an improvement of 75%. At week 52, no loss of efficacy was seen in those participants who had achieved 75% improvement in PASI score at week 16 and had continued their prior doses. The rates of AEs seen in the tildrakizumab groups were 60% to 71% compared to 69% in the placebo group. The most common AE was nasopharyngitis, occurring in 12% to 20% of participants in each group. Serious AEs were uncommon.18 Phase 3 studies are currently underway.19

 

 

Guselkumab

Guselkumab is a human IgG1 monoclonal antibody in clinical development that specifically blocks the p19 subunit of IL-23. In a double-blind, placebo-controlled, phase 1 study, 24 participants with moderate to severe plaque psoriasis were randomized to receive a single 10-mg (n=5), 30-mg (n=5), 100-mg (n=5), or 300-mg (n=5) dose of guselkumab or placebo (n=4).20 At week 12, 50% in the 10-mg group, 60% in both the 30- and 100-mg groups, and 100% in the 300-mg group showed 75% improvement in PASI score versus 0% in the placebo group. Improvements in PASI scores were generally maintained through week 24. The rates of AEs were 65% (13/20) in the combined guselkumab group and 50% (2/4) in the placebo group.20

Small Molecule Inhibitors

In contrast to biologics, which mainly target soluble cytokine or cellular receptors, small molecule inhibitors target enzymes within signaling pathways. Small molecule inhibitors have some advantages over biologics in that they are relatively inexpensive to produce and can be administered orally; thus, they may be preferred by some patients over injectable drugs. There are several agents that are undergoing clinical trials in psoriasis, including PDE4 inhibitors and Jak inhibitors.

Apremilast

Apremilast is an oral small molecule PDE4 inhibitor that was approved by the US Food and Drug Administration in March 2014 for the treatment of adult patients with active psoriatic arthritis; an indication for moderate to severe plaque psoriasis was approved in September 2014.21 Phosphodiesterase 4 is a cyclic adenosine monophosphate–specific phosphodiesterase inhibitor, which is dominant in inflammatory cells. Inhibition of PDE4 increases intracellular cyclic adenosine monophosphate levels, thus downregulating proinflammatory cytokines such as TNF-α, IFN-γ, IL-2, IL-12, and IL-23, and increasing the production of anti-inflammatory cytokines such as IL-10.22

Phase 2 and phase 3 studies have demonstrated the clinical efficacy of apremilast in the treatment of patients with moderate to severe plaque psoriasis. In a 16-week randomized, placebo-controlled, phase 3 trial (ESTEEM 2), 408 participants were randomized to receive oral apremilast 30 mg twice daily (n=275) or placebo (n=138).23 Improvement of 75% in PASI score was achieved by 29% of participants in the apremilast group at week 16. The most common AEs were diarrhea (16%) and nausea (18%), which were predominantly mild, occurring most commonly in the first week and resolving within 1 month. No cases of severe diarrhea or severe nausea were reported. Apremilast had no apparent effect on the results of hematological or serum chemistry tests.23 Although the US Food and Drug Administration warns of a possible link between apremilast and depression,24 data are mostly related to roflumilast, another PDE4 inhibitor. Studies in patients with chronic obstructive pulmonary disease have noted increased cases of depression (1.21% vs 0.82%) and suicidal ideation/attempt (0.03% vs 0.02%) in patients treated with roflumilast versus placebo.25

Jak Inhibitors

Janus kinases are a family of intracellular tyrosine kinases that connect several cytokine receptors to the signal transducer and activator of transcription pathways.26 There are 4 Jak family members: Jak1, Jak2, Jak3, and tyrosine kinase 2. Janus kinases 1 and 2 have roles in interferon signaling, while Jak3 transduces signals from IL-2, IL-7, IL-15, and IL-21, which are T-cell growth and survival factors.

Tofacitinib is a novel oral signal transduction molecule that blocks the Jak3 pathway. A phase 2b, 12-week, dose-ranging study was conducted to assess the efficacy and safety of 3 twice-daily regimens of tofacitinib versus placebo in patients with moderate to severe chronic plaque psoriasis.27 One hundred and ninety-seven participants were randomized to receive oral tofacitinib (2 mg, 5 mg, or 15 mg; n=49 each) or placebo (n=50) twice daily for 12 weeks with a 4-week follow-up period. The primary end point was the proportion of participants achieving at least a 75% reduction in PASI score at week 12 (25.0% with 2 mg, 40.8% with 5 mg, 66.7% with 15 mg, 2.0% with placebo). Similarly, a higher proportion of participants achieving 90% reduction in PASI score was seen at weeks 8 and 12 in all tofacitinib-treated participants versus placebo. The most common AEs were upper respiratory tract infection, sinusitis, nasopharyngitis, and headache. A number of changes in laboratory parameters occurred in the tofacitinib groups. Mild dose-related decreases in hemoglobin were noted at week 12 for all tofacitinib groups, and a small increase (mean, 0.04 mg/dL) in serum creatinine levels was observed in the 15-mg group. Decreases in neutrophil counts were observed with higher doses of tofacitinib, with the maximum mean decrease of 0.9×103/mm3 from baseline observed in the 15-mg group at week 4. After weeks 4 through 8, mean neutrophil counts began to return to baseline levels. Dose-related increases in total cholesterol, high-density lipoprotein cholesterol, and low-density lipoprotein cholesterol were observed by week 2 and remained at this level through week 12; mean lipid levels decreased to baseline levels after cessation of active treatment. One participant in the 15-mg group developed an elevated alanine aminotransferase level that was more than 2.5 times the highest normal limit. Three participants experienced 5 serious AEs.27 These early results show that tofacitinib can be a safe and effective treatment in patients with psoriasis, but further data from phase 3 studies will need to be awaited.

 

 

Another Jak inhibitor under investigationfor the treatment of psoriasis is ruxolitinib, an inhibitor of Jak1 and Jak2, which has been primarily studied as a topical agent for milder cases of the disease.28

Conclusion

Many new drugs are currently on the horizon and will increase our armamentarium for treating psoriasis. Some of these agents promise greater levels of efficacy than currently used therapies. Although this review focuses on systemic agents, there also are a number of topical formulations in the pipeline. These new agents will certainly increase our options when choosing the most suitable treatment for a patient with psoriasis, but safety will remain a primary concern, and time and experience will tell whether efficacy outweighs any potential side effects.

Psoriasis is a common chronic inflammatory skin disease affecting 1% to 8% of the world population, depending on the country.1 Psoriasis can greatly impact quality of life in affected individuals, even in those with limited body surface involvement.2 Studies have demonstrated a high degree of psychological distress associated with psoriasis, leading to depression and poor self-esteem.3

Over the last decade, our improved understanding of the autoimmune inflammatory pathways and the associated changing concepts in psoriasis pathogenesis have led to the development of biological drugs targeting specific components of effector immune mechanisms, and these biological drugs have revolutionized the treatment of psoriasis.4 Although response rates of these biological agents are greater compared to those of conventional systemic drugs,5 current biological drugs fail to demonstrate efficacy in some patients or lose their efficacy over time. In addition to the high costs associated with these drugs, these limitations have driven a continued search for alternative therapies.

Helper T cells (TH17) and the proinflammatory cytokine IL-17 have been shown to play a key role in the pathophysiology of psoriasis, bridging innate and adaptive immune responses. IL-17 is involved in the modulation of proinflammatory cytokines, hematopoietic growth factors, antimicrobial peptides, and chemokines. Increased TH17 activity and high levels of IL-17 have been found in psoriatic plaques, and increased levels of TH17 are found in the plasma of psoriasis patients.6 Increased IL-17 induces neutrophilia, inflammation, and angiogenesis.7 Other cytokines that are highly upregulated in involved skin are tumor necrosis factor a (TNF-α), IL-23, IL-22, and IL-21.8 IL-23 is involved in regulating TH17 cells and is a potent activator of keratinocyte proliferation.9 Blockade of IL-12/23 causes downregulation of TH17 and TH22 cell responses.10 As IL-17 has a key role in protecting skin and mucous membranes from bacterial and fungal infections, IL-17 inhibition can potentially interfere with the inflammatory cascade. However, available data suggest that sufficient residual IL-17 activity remains to maintain immunity against infections.11

Currently approved biological agents for psoriasis target proinflammatory cytokines such as TNF-α, or the p40 subunit of IL-12 and IL-23. A number of novel targeted therapies including biologics as well as small molecule inhibitors targeting various cytokines and molecules involved in the pathogenesis of psoriasis are currently in different stages of development (Table). These drugs include 3 IL-17 inhibitors (secukinumab, ixekizumab, and brodalumab); 2 IL-23 blockers (tildrakizumab and guselkumab); and small molecule inhibitors that target the kinase pathway including apremilast (a phosphodiesterase 4 [PDE4] inhibitor), as well as tofacitinib, baricitinib, and ruxolitinib (Janus kinase [Jak] inhibitors). Small molecule inhibitors can be administered orally and are less expensive to produce than biological agents. This article reviews available data on these new systemic agents in the pipeline.

Novel Biologics

Secukinumab

Secukinumab is a fully human monoclonal IgG1k antibody that selectively binds and neutralizes IL-17A.12 It is the first of the IL-17 antibodies to receive approval for the treatment of moderate to severe psoriasis. In 2 phase 3, double-blind, 52-week trials—ERASURE (Efficacy of Response and Safety of Two Fixed Secukinumab Regimens in Psoriasis) and FIXTURE (Full Year Investigative Examination of Secukinumab vs Etanercept Using Two Dosing Regimens to Determine Efficacy in Psoriasis)—participants were randomly assigned to receive subcutaneous secukinumab at doses of 300 mg (n=245 and n=327, respectively) or 150 mg (n=245 and n=327, respectively) once weekly for 5 weeks then every 4 weeks, or placebo (n=248 and n=326, respectively); in the FIXTURE study only, an etanercept group (n=326) was given a 50-mg dose twice weekly for 12 weeks then once weekly.13

In the ERASURE study, the proportion of participants showing a reduction of 75% or more in psoriasis area and severity index (PASI) score from baseline to week 12 was 81.6% with secukinumab 300 mg, 71.6% with secukinumab 150 mg, and 4.5% with placebo.13 Secondary end point results demonstrated the proportion of participants showing a 90% reduction in PASI score was 59.2% with secukinumab 300 mg and 39.1% with secukinumab 150 mg, which were both superior to placebo (1.2%). The proportion of participants who met the criteria for 100% reduction in PASI score at week 12 also was greater with each secukinumab dose than with placebo.13

In the FIXTURE study, the proportion of participants showing a reduction of 75% or more from baseline in PASI score at week 12 was 77.1% with secukinumab 300 mg, 67.0% with secukinumab 150 mg, 44.0% with etanercept, and 4.9% with placebo.13 Secondary end point results demonstrated the proportion of participants showing a 90% reduction in PASI score was 54.2% with secukinumab 300 mg, 41.9% with secukinumab 150 mg, 20.7% with etanercept, and 1.5% with placebo. The speed of response, which was assessed as the median time to a 50% reduction in mean PASI score from baseline, was significantly shorter with both doses of secukinumab (3.0 weeks and 3.9 weeks, respectively) than with etanercept (7.0 weeks)(P<.001 for both).13

 

 

In the FIXTURE study, incidences of adverse events (AEs) were similar in the secukinumab and etanercept groups during both the induction period and the entire treatment period.13 The most common AEs in the secukinumab groups were nasopharyngitis, headache, and diarrhea. The rates of infections or infestations during the induction period were 26.7% with secukinumab 300 mg, 30.9% with secukinumab 150 mg, 24.5% with etanercept, and 19.3% with placebo. Candidal infections were more common with secukinumab than with etanercept during the entire treatment period (4.7% and 2.3% of participants in the secukinumab 300 mg and 150 mg groups, respectively, reported mild or moderate candidal infections). None of these infections resulted in chronic mucocutaneous candidiasis or discontinuation of the study drug and all resolved on their own or with standard therapy. Candidal infection was reported in 1.2% of participants in the etanercept group. Responses at week 12 were sustained in the majority of participants through week 52 with continued secukinumab therapy every 4 weeks. Grade 3 neutropenia occurred in 1.0% of secukinumab-treated participants and in none of the participants in the etanercept group. There were no apparent dose-related differences between the secukinumab groups with respect to AEs, with the exception of mild and moderate candidal infections.13

These efficacy data are impressive and no specific serious safety concerns have been identified to date. However, IL-17A plays a key role in host defense, particularly in mucocutaneous immunity against Candida albicans,14 as well as in hematopoiesis through stimulation of granulopoiesis and neutrophil trafficking,15 and thus we need to remain watchful with regards to Candida albicans infections and neutropenia.

Ixekizumab

Ixekizumab is a humanized IgG4 anti–IL-17A monoclonal antibody. In a phase 2, double-blind, placebo-controlled trial, 142 participants with chronic moderate to severe plaque psoriasis were randomly assigned to receive 150-mg (n=28), 75-mg (n=29), 25-mg (n=30), or 10-mg (n=28) subcutaneous injections of ixekizumab or placebo (n=27) at weeks 0, 2, 4, 8, 12, and 16.16 At 12 weeks, the percentage of participants who achieved a 75% reduction in PASI score from baseline was significantly greater with ixekizumab (82.1% with 150-mg dose, 82.8% with 75-mg dose, 76.7% with 25-mg dose) than with placebo (7.7%)(P<.001 for each comparison), except with the 10-mg dose. Similarly, a greater percentage of participants in the same ixekizumab groups achieved a 90% reduction (71.4% with 150-mg dose, 58.6% with 75-mg dose, 50.0% with 25-mg dose) and a 100% reduction (39.3% with 150-mg dose, 37.9% with 75-mg dose) in PASI score compared to placebo (0%)(P<.001 for each comparison). Significant reductions in PASI scores were evident as early as week 1 in the 150-mg and 75-mg groups, and these reductions were sustained for 20 weeks (P<.05).16 Phase 3 studies of ixekizumab currently are underway.

Brodalumab

The third IL-17 blocker in the pipeline is brodalumab, a human monoclonal antibody against IL-17RA, which blocks signaling of IL-17A and IL-17F as well as the IL-17A/F heterodimer, all of which are involved in the inflammatory process of psoriasis. Brodalumab was evaluated in a phase 2, double-blind, placebo-controlled, dose-ranging study of 198 participants who were randomized to receive 70 mg (n=39), 140 mg (n=39), 210 mg (n=40), or 280 mg (n=42) of brodalumab or placebo (n=38).17 At week 12, improvements of at least 75% and at least 90% in PASI score were achieved by 77% and 72%, respectively, in the 140-mg group, and 82% and 75%, respectively, in the 210-mg group compared to 0% of the placebo group (P<.001 for all comparisons). One hundred percent improvement in PASI was achieved by 38% of participants in the 140-mg group and 62% in the 210-mg group. No participants in the placebo group demonstrated improvement of 75% or higher. The most common AEs were nasopharyngitis, upper respiratory tract infection, arthralgia, and injection-site erythema. Serious AEs reported during the study included renal colic (1 participant), ec-topic pregnancy (1 participant), and grade 3 asymptomatic neutropenia (2 participants). Both cases of neutropenia were noted at the first assessment after brodalumab initiation (week 2) and resolved when the study drug was withheld.17

Results for this new IL-17 blocker are encouraging, but phase 3 data of brodalumab will need to be awaited.

Tildrakizumab

Tildrakizumab is a humanized IgG1 monoclonal antibody that blocks the p19 subunit of IL-23. In a randomized, double-blind, phase 2b trial, 355 adults with moderate to severe psoriasis were randomized to receive subcutaneous injections of tildrakizumab (5 mg, 25 mg, 100 mg, or 200 mg) or placebo.18 In part 1 of the study, injections were administered at weeks 0 and 4. Part 2 of the study started at week 16. In part 2, responders with a 75% improvement in PASI score in the 5- and 25-mg groups continued their dose, while responders in the 100- or 200-mg groups were randomized again to continue the same dose or a reduced dose (100 mg to 25 mg; 200 mg to 100 mg) every 12 weeks from weeks 16 to 52. Those in the placebo group received tildrakizumab 25 mg every 12 weeks in part 2. The primary end point was the mean change in PASI score from baseline to week 16, which was significantly greater in all tildrakizumab groups than in the placebo group (P<.001 for all comparisons). Improvements of 75% in PASI score were achieved by 74% in the 200-mg group, 66% in the 100-mg group, 64% in the 25-mg group, and 33% in the 5-mg group. In contrast, 4.9% in the placebo group achieved an improvement of 75%. At week 52, no loss of efficacy was seen in those participants who had achieved 75% improvement in PASI score at week 16 and had continued their prior doses. The rates of AEs seen in the tildrakizumab groups were 60% to 71% compared to 69% in the placebo group. The most common AE was nasopharyngitis, occurring in 12% to 20% of participants in each group. Serious AEs were uncommon.18 Phase 3 studies are currently underway.19

 

 

Guselkumab

Guselkumab is a human IgG1 monoclonal antibody in clinical development that specifically blocks the p19 subunit of IL-23. In a double-blind, placebo-controlled, phase 1 study, 24 participants with moderate to severe plaque psoriasis were randomized to receive a single 10-mg (n=5), 30-mg (n=5), 100-mg (n=5), or 300-mg (n=5) dose of guselkumab or placebo (n=4).20 At week 12, 50% in the 10-mg group, 60% in both the 30- and 100-mg groups, and 100% in the 300-mg group showed 75% improvement in PASI score versus 0% in the placebo group. Improvements in PASI scores were generally maintained through week 24. The rates of AEs were 65% (13/20) in the combined guselkumab group and 50% (2/4) in the placebo group.20

Small Molecule Inhibitors

In contrast to biologics, which mainly target soluble cytokine or cellular receptors, small molecule inhibitors target enzymes within signaling pathways. Small molecule inhibitors have some advantages over biologics in that they are relatively inexpensive to produce and can be administered orally; thus, they may be preferred by some patients over injectable drugs. There are several agents that are undergoing clinical trials in psoriasis, including PDE4 inhibitors and Jak inhibitors.

Apremilast

Apremilast is an oral small molecule PDE4 inhibitor that was approved by the US Food and Drug Administration in March 2014 for the treatment of adult patients with active psoriatic arthritis; an indication for moderate to severe plaque psoriasis was approved in September 2014.21 Phosphodiesterase 4 is a cyclic adenosine monophosphate–specific phosphodiesterase inhibitor, which is dominant in inflammatory cells. Inhibition of PDE4 increases intracellular cyclic adenosine monophosphate levels, thus downregulating proinflammatory cytokines such as TNF-α, IFN-γ, IL-2, IL-12, and IL-23, and increasing the production of anti-inflammatory cytokines such as IL-10.22

Phase 2 and phase 3 studies have demonstrated the clinical efficacy of apremilast in the treatment of patients with moderate to severe plaque psoriasis. In a 16-week randomized, placebo-controlled, phase 3 trial (ESTEEM 2), 408 participants were randomized to receive oral apremilast 30 mg twice daily (n=275) or placebo (n=138).23 Improvement of 75% in PASI score was achieved by 29% of participants in the apremilast group at week 16. The most common AEs were diarrhea (16%) and nausea (18%), which were predominantly mild, occurring most commonly in the first week and resolving within 1 month. No cases of severe diarrhea or severe nausea were reported. Apremilast had no apparent effect on the results of hematological or serum chemistry tests.23 Although the US Food and Drug Administration warns of a possible link between apremilast and depression,24 data are mostly related to roflumilast, another PDE4 inhibitor. Studies in patients with chronic obstructive pulmonary disease have noted increased cases of depression (1.21% vs 0.82%) and suicidal ideation/attempt (0.03% vs 0.02%) in patients treated with roflumilast versus placebo.25

Jak Inhibitors

Janus kinases are a family of intracellular tyrosine kinases that connect several cytokine receptors to the signal transducer and activator of transcription pathways.26 There are 4 Jak family members: Jak1, Jak2, Jak3, and tyrosine kinase 2. Janus kinases 1 and 2 have roles in interferon signaling, while Jak3 transduces signals from IL-2, IL-7, IL-15, and IL-21, which are T-cell growth and survival factors.

Tofacitinib is a novel oral signal transduction molecule that blocks the Jak3 pathway. A phase 2b, 12-week, dose-ranging study was conducted to assess the efficacy and safety of 3 twice-daily regimens of tofacitinib versus placebo in patients with moderate to severe chronic plaque psoriasis.27 One hundred and ninety-seven participants were randomized to receive oral tofacitinib (2 mg, 5 mg, or 15 mg; n=49 each) or placebo (n=50) twice daily for 12 weeks with a 4-week follow-up period. The primary end point was the proportion of participants achieving at least a 75% reduction in PASI score at week 12 (25.0% with 2 mg, 40.8% with 5 mg, 66.7% with 15 mg, 2.0% with placebo). Similarly, a higher proportion of participants achieving 90% reduction in PASI score was seen at weeks 8 and 12 in all tofacitinib-treated participants versus placebo. The most common AEs were upper respiratory tract infection, sinusitis, nasopharyngitis, and headache. A number of changes in laboratory parameters occurred in the tofacitinib groups. Mild dose-related decreases in hemoglobin were noted at week 12 for all tofacitinib groups, and a small increase (mean, 0.04 mg/dL) in serum creatinine levels was observed in the 15-mg group. Decreases in neutrophil counts were observed with higher doses of tofacitinib, with the maximum mean decrease of 0.9×103/mm3 from baseline observed in the 15-mg group at week 4. After weeks 4 through 8, mean neutrophil counts began to return to baseline levels. Dose-related increases in total cholesterol, high-density lipoprotein cholesterol, and low-density lipoprotein cholesterol were observed by week 2 and remained at this level through week 12; mean lipid levels decreased to baseline levels after cessation of active treatment. One participant in the 15-mg group developed an elevated alanine aminotransferase level that was more than 2.5 times the highest normal limit. Three participants experienced 5 serious AEs.27 These early results show that tofacitinib can be a safe and effective treatment in patients with psoriasis, but further data from phase 3 studies will need to be awaited.

 

 

Another Jak inhibitor under investigationfor the treatment of psoriasis is ruxolitinib, an inhibitor of Jak1 and Jak2, which has been primarily studied as a topical agent for milder cases of the disease.28

Conclusion

Many new drugs are currently on the horizon and will increase our armamentarium for treating psoriasis. Some of these agents promise greater levels of efficacy than currently used therapies. Although this review focuses on systemic agents, there also are a number of topical formulations in the pipeline. These new agents will certainly increase our options when choosing the most suitable treatment for a patient with psoriasis, but safety will remain a primary concern, and time and experience will tell whether efficacy outweighs any potential side effects.

References

 

1. Parisi R, Symmons DP, Griffiths CE, et al. Global epidemiology of psoriasis: a systematic review of incidence and prevalence. J Invest Dermatol. 2013;133:377-385.

2. Rapp SR, Feldman SR, Exum ML, et al. Psoriasis causes as much disability as other major medical diseases. J Am Acad Dermatol. 1999;41(3 pt 1):401-407.

3. Shah R, Bewley A. Psoriasis: ‘the badge of shame.’ a case report of a psychological intervention to reduce and potentially clear chronic skin disease. Clin Exp Dermatol. 2014;39:600-603.

4. Vincent FB, Morand EF, Murphy K, et al. Antidrug antibodies (ADAb) to tumour necrosis factor (TNF)-specific neutralising agents in chronic inflammatory diseases: a real issue, a clinical perspective. Ann Rheum Dis. 2013;72:165-178.

5. Chi CC, Wang SH. Efficacy and cost-efficacy of biologic therapies for moderate to severe psoriasis: a meta-analysis and cost-efficacy analysis using the intention-to-treat principle. Biomed Res Int. 2014;2014:862851.

6. Kagami S, Rizzo HL, Lee JJ, et al. Circulating Th17, Th22, and Th1 cells are increased in psoriasis. J Invest Dermatol. 2010;130:1373-1383.

7. Leonardi CL, Gordon KB. New and emerging therapies in psoriasis. Semin Cutan Med Surg. 2014;33(2, suppl 2):S37-S41.

8. Lowes MA, Kikuchi T, Fuentes-Duculan J, et al. Psoriasis vulgaris lesions contain discrete populations of Th1 and Th17 T cells. J Invest Dermatol. 2008;128:1207-1211.

9. Nickoloff BJ, Qin JZ, Nestle FO. Immunopathogenesis of psoriasis. Clin Rev Allergy Immunol. 2007;33:45-56.

10. Fitch E, Harper E, Skorcheva I, et al. Pathophysiology of psoriasis: recent advances on IL-23 and Th17 cytokines. Curr Rheumatol Rep. 2007;9:461-467.

11. Adami S, Cavani A, Rossi F, et al. The role of interleukin-17A in psoriatic disease. BioDrugs. 2014;28:487-497.

12. Hueber W, Patel DD, Dryja T, et al. Effects of AIN457, a fully human antibody to interleukin-17A, on psoriasis, rheumatoid arthritis, and uveitis. Sci Transl Med. 2010;2:52ra72.

13. Langley RG, Elewski BE, Lebwohl M, et al. Secukinumab in plaque psoriasis—results of two phase 3 trials. N Engl J Med. 2014;371:326-338.

14. Puel A, Cypowyj S, Bustamante J, et al. Chronic mucocutaneous candidiasis in humans with inborn errors of interleukin-17 immunity. Science. 2011;332:65-68.

15. Krstic A, Mojsilovic S, Jovcic G, et al. The potential of interleukin-17 to mediate hematopoietic response. Immunol Res. 2012;52:34-41.

16. Leonardi C, Matheson R, Zachariae C, et al. Anti-interleukin-17 monoclonal antibody ixekizumab in chronic plaque psoriasis. N Engl J Med. 2012;366:1190-1199.

17. Papp KA, Leonardi C, Menter A, et al. Brodalumab, an anti-interleukin-17-receptor antibody for psoriasis. N Engl J Med. 2012;366:1181-1189.

18. Langley RGB, Thaci D, Papp KA, et al. MK-3222, an anti–IL-23p19 humanized monoclonal antibody, provides significant improvement in psoriasis over 52 weeks of treatment that is maintained after discontinuation of dosing. Poster presented at: 73rd Annual Meeting of the American Academy of Dermatology; March 21-25, 2014; Denver, CO. Poster 8056.

19. Tausend W, Downing C, Tyring S. Systematic review of interleukin-12, interleukin-17, and interleukin-23 pathway inhibitors for the treatment of moderate-to-severe chronic plaque psoriasis: ustekinumab, briakinumab, tildrakizumab, guselkumab, secukinumab, ixekizumab, and brodalumab. J Cutan Med Surg. 2014;18:156-169.

20. Sofen H, Smith S, Matheson RT, et al. Guselkumab (an IL-23-specific mAb) demonstrates clinical and molecular response in patients with moderate-to-severe psoriasis. J Allergy Clin Immunol. 2014;133:1032-1040.

21. Schafer PH, Parton A, Capone L, et al. Apremilast is a selective PDE4 inhibitor with regulatory effects on innate immunity. Cell Signal. 2014;26:2016-2029.

22. van de Kerkhof PC. Apremilast: a step forward in the treatment of psoriasis? Lancet. 2012;380:708-709.

23. Paul C, Crowley J, Cather J, et al. Apremilast, an oral phosphodiesterase 4 inhibitor, in patients with moderate to severe psoriasis: 16-week results of a phase 3, randomized, controlled trial (ESTEEM 2). Poster presented at: 73rd Annual Meeting of the American Academy of Dermatology; March 21-25, 2014; Denver, CO. Poster 8412.

24. Otezla [product insert]. Summit, NJ: Celgene Corporation; 2014.

25. Rabe KF. Update on roflumilast, a phosphodiesterase 4 inhibitor for the treatment of chronic obstructive pulmonary disease. Br J Pharmacol. 2011;163:53-67.

26. Palanivel JA, Macbeth AE, Chetty NC, et al. An insight into JAK-STAT signalling in dermatology. Clin Exp Dermatol. 2014;39:513-518.

27. Papp KA, Menter A, Strober B, et al. Efficacy and safety of tofacitinib, an oral Janus kinase inhibitor, in the treatment of psoriasis: a phase 2b randomized placebo-controlled dose-ranging study. Br J Dermatol. 2012;167:668-677.

28. Hsu L, Armstrong AW. JAK inhibitors: treatment efficacy and safety profile in patients with psoriasis. J Immunol Res. 2014;2014:283617.

References

 

1. Parisi R, Symmons DP, Griffiths CE, et al. Global epidemiology of psoriasis: a systematic review of incidence and prevalence. J Invest Dermatol. 2013;133:377-385.

2. Rapp SR, Feldman SR, Exum ML, et al. Psoriasis causes as much disability as other major medical diseases. J Am Acad Dermatol. 1999;41(3 pt 1):401-407.

3. Shah R, Bewley A. Psoriasis: ‘the badge of shame.’ a case report of a psychological intervention to reduce and potentially clear chronic skin disease. Clin Exp Dermatol. 2014;39:600-603.

4. Vincent FB, Morand EF, Murphy K, et al. Antidrug antibodies (ADAb) to tumour necrosis factor (TNF)-specific neutralising agents in chronic inflammatory diseases: a real issue, a clinical perspective. Ann Rheum Dis. 2013;72:165-178.

5. Chi CC, Wang SH. Efficacy and cost-efficacy of biologic therapies for moderate to severe psoriasis: a meta-analysis and cost-efficacy analysis using the intention-to-treat principle. Biomed Res Int. 2014;2014:862851.

6. Kagami S, Rizzo HL, Lee JJ, et al. Circulating Th17, Th22, and Th1 cells are increased in psoriasis. J Invest Dermatol. 2010;130:1373-1383.

7. Leonardi CL, Gordon KB. New and emerging therapies in psoriasis. Semin Cutan Med Surg. 2014;33(2, suppl 2):S37-S41.

8. Lowes MA, Kikuchi T, Fuentes-Duculan J, et al. Psoriasis vulgaris lesions contain discrete populations of Th1 and Th17 T cells. J Invest Dermatol. 2008;128:1207-1211.

9. Nickoloff BJ, Qin JZ, Nestle FO. Immunopathogenesis of psoriasis. Clin Rev Allergy Immunol. 2007;33:45-56.

10. Fitch E, Harper E, Skorcheva I, et al. Pathophysiology of psoriasis: recent advances on IL-23 and Th17 cytokines. Curr Rheumatol Rep. 2007;9:461-467.

11. Adami S, Cavani A, Rossi F, et al. The role of interleukin-17A in psoriatic disease. BioDrugs. 2014;28:487-497.

12. Hueber W, Patel DD, Dryja T, et al. Effects of AIN457, a fully human antibody to interleukin-17A, on psoriasis, rheumatoid arthritis, and uveitis. Sci Transl Med. 2010;2:52ra72.

13. Langley RG, Elewski BE, Lebwohl M, et al. Secukinumab in plaque psoriasis—results of two phase 3 trials. N Engl J Med. 2014;371:326-338.

14. Puel A, Cypowyj S, Bustamante J, et al. Chronic mucocutaneous candidiasis in humans with inborn errors of interleukin-17 immunity. Science. 2011;332:65-68.

15. Krstic A, Mojsilovic S, Jovcic G, et al. The potential of interleukin-17 to mediate hematopoietic response. Immunol Res. 2012;52:34-41.

16. Leonardi C, Matheson R, Zachariae C, et al. Anti-interleukin-17 monoclonal antibody ixekizumab in chronic plaque psoriasis. N Engl J Med. 2012;366:1190-1199.

17. Papp KA, Leonardi C, Menter A, et al. Brodalumab, an anti-interleukin-17-receptor antibody for psoriasis. N Engl J Med. 2012;366:1181-1189.

18. Langley RGB, Thaci D, Papp KA, et al. MK-3222, an anti–IL-23p19 humanized monoclonal antibody, provides significant improvement in psoriasis over 52 weeks of treatment that is maintained after discontinuation of dosing. Poster presented at: 73rd Annual Meeting of the American Academy of Dermatology; March 21-25, 2014; Denver, CO. Poster 8056.

19. Tausend W, Downing C, Tyring S. Systematic review of interleukin-12, interleukin-17, and interleukin-23 pathway inhibitors for the treatment of moderate-to-severe chronic plaque psoriasis: ustekinumab, briakinumab, tildrakizumab, guselkumab, secukinumab, ixekizumab, and brodalumab. J Cutan Med Surg. 2014;18:156-169.

20. Sofen H, Smith S, Matheson RT, et al. Guselkumab (an IL-23-specific mAb) demonstrates clinical and molecular response in patients with moderate-to-severe psoriasis. J Allergy Clin Immunol. 2014;133:1032-1040.

21. Schafer PH, Parton A, Capone L, et al. Apremilast is a selective PDE4 inhibitor with regulatory effects on innate immunity. Cell Signal. 2014;26:2016-2029.

22. van de Kerkhof PC. Apremilast: a step forward in the treatment of psoriasis? Lancet. 2012;380:708-709.

23. Paul C, Crowley J, Cather J, et al. Apremilast, an oral phosphodiesterase 4 inhibitor, in patients with moderate to severe psoriasis: 16-week results of a phase 3, randomized, controlled trial (ESTEEM 2). Poster presented at: 73rd Annual Meeting of the American Academy of Dermatology; March 21-25, 2014; Denver, CO. Poster 8412.

24. Otezla [product insert]. Summit, NJ: Celgene Corporation; 2014.

25. Rabe KF. Update on roflumilast, a phosphodiesterase 4 inhibitor for the treatment of chronic obstructive pulmonary disease. Br J Pharmacol. 2011;163:53-67.

26. Palanivel JA, Macbeth AE, Chetty NC, et al. An insight into JAK-STAT signalling in dermatology. Clin Exp Dermatol. 2014;39:513-518.

27. Papp KA, Menter A, Strober B, et al. Efficacy and safety of tofacitinib, an oral Janus kinase inhibitor, in the treatment of psoriasis: a phase 2b randomized placebo-controlled dose-ranging study. Br J Dermatol. 2012;167:668-677.

28. Hsu L, Armstrong AW. JAK inhibitors: treatment efficacy and safety profile in patients with psoriasis. J Immunol Res. 2014;2014:283617.

Issue
Cutis - 95(3)
Issue
Cutis - 95(3)
Page Number
155-160
Page Number
155-160
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New Systemic Therapies for Psoriasis
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New Systemic Therapies for Psoriasis
Legacy Keywords
Psoriasis, chronic inflammatory skin disease, Tildrakizumab, Guselkumab, Ixekizumab, Secukinumab, Jak Inhibitors, Apremilast, Tofacitinib, biological agents, biologics, small molecule inhibitors
Legacy Keywords
Psoriasis, chronic inflammatory skin disease, Tildrakizumab, Guselkumab, Ixekizumab, Secukinumab, Jak Inhibitors, Apremilast, Tofacitinib, biological agents, biologics, small molecule inhibitors
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      Practice Points

 

  • ­Secukinumab is an anti–IL-17 antibody approved for the treatment of psoriasis. It is indicated for the treatment of moderate to severe plaque psoriasis in adult patients who are candidates for systemic therapy or phototherapy.
  • ­The new biological agents have shown promising results with some patients achieving psoriasis area and severity index scores of 90 and 100.
  • ­A number of small molecule inhibitors also are in the pipeline, with apremilast the first one to have reached approval for psoriasis.
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