Your search keyword '"Levin, YS"' showing total 6 results

1. Strategies for overcoming obstacles to hands-on cosmetic and laser training in dermatology residency.

Author

Kang BY, Aristizabal M, Stratman EJ, Hu JC, Petronic-Rosic V, Minkis K, Elsanadi R, Alvarez G, Nadir U, Kelly KM, Saikaly SK, Bolotin D, Levin YS, Orringer JS, and Alam M

Abstract

Competing Interests: Conflicts of interest None disclosed

Published

2025

2. Updates in the Management of Congenital Melanocytic Nevi.

Author

Mologousis MA, Tsai SY, Tissera KA, Levin YS, and Hawryluk EB

Abstract

Congenital melanocytic nevi (CMN) carry an increased risk of melanoma and may be disfiguring, and consensus regarding treatment recommendations is lacking. While clinical monitoring is the standard of care, many caregivers are interested in its removal to prevent psychosocial burden or to decrease risk. Although melanoma can occur regardless of CMN removal, there are a variety of treatments that may offer improved cosmesis or local symptom control, including surgical excision, laser therapy, and other superficially destructive techniques. Regardless of the selected management, these patients are monitored for ongoing melanoma risk. An extensive discussion with families regarding the risks and benefits of observation versus active intervention is essential. To facilitate these discussions, we herein summarize current CMN management strategies and considerations.

Published

2024

3. Training the Next Generation of Clinician-Innovators: The Virtual Magic Wand Program.

Author

Levin YS, Lee KC, Raff AB, Breslin JJ, Ju W, and Garibyan L

Published

2022

4. Cosmetic dermatology in menopause.

Author

Levin YS

Subjects

Female, Humans, Menopause, Rejuvenation, Cosmetic Techniques adverse effects, Dermatology, Skin Aging

Abstract

Abstract: Skin changes that accompany aging lead many to seek treatments that restore a more youthful appearance. Common issues of concern include skin tone, wrinkles, skin thinning, sagging, laxity and decreased elasticity, and hollowing of the face. This work discusses these concerns and their anatomic bases and highlights evidence for a causal role played by menopause-associated hormonal changes where such evidence exists. In addition, treatment options are discussed, with an emphasis on minimally invasive approaches. A variety of modalities are discussed, including botulinum toxins, fillers, multiple types of lasers, radiofrequency devices, focused ultrasound, chemical peels, and thread lifts. These interventions, often in combination, can achieve goals of patients seeking aesthetic rejuvenation., Competing Interests: Financial disclosures/Conflicts of interest: Dr. Levin receives funding from Pulse Biosciences (consultancy unrelated to manuscript) and owns stock in Avava Soltego Accure (unrelated to the manuscript)., (Copyright © 2022 by The North American Menopause Society.)

Published

2022

5. Multifunctional patch for use during laser procedures: Optimization and feasibility testing.

Author

Levin YS, Islam R, Avram MM, Franco W, and Anderson RR

Subjects

Feasibility Studies, Particulate Matter, Hair Removal, Laser Therapy, Lasers, Solid-State

Abstract

Objective: The objective of this study was to develop a patch that can be placed on the skin during laser hair removal and similar procedures, that serves to reduce the laser-induced plume, provides a ready indicator to the laser surgeon of where pulses have been applied, and cools the skin., Methods: A two-layer patch composed of a cooling hydrogel layer and an indicator layer was optimized and tested ex vivo. The hydrogel was composed of gelatin and glycerin. The concentration of each hydrogel component was optimized to determine the minimum gelatin concentration at which the gel can be handled without breakage and the minimum glycerin concentration that allows for storage at -20°C without crystallization. This is the temperature of a conventional freezer; application of the cooling layer to the skin would help prevent epidermal injury. The indicator layer was composed of a plastic transparency sheet with small dots of black ink particles printed onto its surface. Transparency sheets were printed from templates created in Adobe Photoshop in which dots are at a specified density; additionally, Photoshop's opacity function was used to vary the opacity of the dots themselves. Performance was tested using a 755 nm alexandrite laser used clinically for hair removal by measuring light transmission through the patch and observing the sheet's ability to indicate the location of laser exposures. The transmittance of patch components across a broad spectrum was also measured using a microplate reader. Several adhesives, including a two-part epoxy, silicone rubber, and cyanoacrylate, were tested for their ability to adhere to the hydrogel and indicator layers. Assembled patches composed of the hydrogel layer, indicator layer, and adhesive were tested ex vivo for their ability to mitigate the laser hair removal plume by measuring airborne particulate matter during simulated laser hair removal., Results: A minimum gelatin concentration of 5% was found to enable easy handling of the hydrogel. A mixture composed of 60% water and 40% glycerin by volume consistently allowed storage at -20°C without crystallization. For the indicator layer, ink particle density of 50% and opacity of 5% provided a readily apparent indicator function following laser exposure. Transmission through the sheet measured during alexandrite laser exposures was 90% and was not different than transmission through the sheet alone without ink particles. A cyanoacrylate glue was found to adhere to the hydrogel and indicator layers, while the other adhesives proved inadequate. Measurements using a microplate reader confirmed that the reflection from the transparency sheet itself was the primary contributor to energy loss. In experiments exposing hair clippings to the laser with and without the patch, the patch allowed an increase of 5000 particles/cc relative to baseline particles in the environmental air, while the absence of the patch allowed an increase of 150,000 particles/cc relative to baseline, indicating that the patch decreased particle debris in the plume by 97%., Conclusions: A two-layer patch composed of hydrogel and plastic indicator layer with cyanoacrylate adhesive can be stored in a conventional freezer without crystallization, then placed over an area of skin to be treated for laser hair removal. The patch clearly indicates the pattern and sites of laser exposure, while blocking almost all (97%) of particles in the laser-induced plume. Future work will include safety validation and in vivo testing of efficacy, as these were not undertaken in this study., (© 2021 Wiley Periodicals LLC.)

Published

2022

6. Gaseous and Particulate Content of Laser Tattoo Removal Plume.

Author

Levin YS, Grant MP, Glassford E, Green BJ, Lemons AR, and Avram MM

Subjects

Air analysis, Animals, Gases adverse effects, Humans, Ink, Models, Animal, Occupational Exposure standards, Particle Size, Particulate Matter adverse effects, Skin radiation effects, Swine, Gases analysis, Lasers, Solid-State, Occupational Exposure adverse effects, Particulate Matter analysis, Tattooing adverse effects

Abstract

Background: There is increasing awareness of the potential hazards of surgical plumes. The plume associated with laser tattoo removal remains uncharacterized., Objective: To determine the gaseous, particulate, and microbiological content of the laser tattoo removal plume., Materials and Methods: Air sampling was performed during laser tattoo removal from pig skin and from patients. Measurement of metals, volatile organic compounds (VOCs), carbon monoxide (CO), hydrogen sulfide (HS), and ultrafine particulates (UPs) as well as bacterial 16S ribosomal DNA sequencing were performed., Results: Metals were identified in the plume from both pig and human skin. Volatile organic compounds were found at similar levels within and outside the treatment room. Several bacterial phyla were detected in the treatment room, but not outside. High levels of UPs were measured throughout the treatment room during tattoo removal from pig skin. Ultrafine particulates were detected at low levels in the room periphery during tattoo removal from human skin, but at higher levels in the immediate treatment zone. HS and CO were not detected., Conclusion: Metals, VOCs, HS, and CO were found at levels below applicable occupational exposure limits. The presence of bacteria is of uncertain significance, but may be hazardous. High levels of UPs require further investigation., (Copyright © 2021 by the American Society for Dermatologic Surgery, Inc. Published by Wolters Kluwer Health, Inc. All rights reserved.)

Published

2021