The effects of pulse energy variations on the dimensions of microscopic thermal treatment zones in nonablative fractional resurfacing

Bedi, Vikramaditya P.; Chan, Kin Foong; Sink, R. K.; Hantash, Basil M.; Herron, G. Scott; Rahman, Zakia; Struck, Steven K.; Zachary, Christopher B.

doi:10.1002/lsm.20406

Cited by 76 publications

(92 citation statements)

References 15 publications

(18 reference statements)

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“…In a previous study, we recognized the limitation of vertical sectioning accurately locating the widest and deepest boundaries of a lesion [18]. To overcome this limitation, we decided to utilize a horizontal serial frozen sectioning technique that allowed visualization of the true center of each cavity thus providing a more precise estimate of lesion width.…”

Section: Resultsmentioning

confidence: 99%

“…The laser handpiece was translated at a specific velocity by using a precision linear stage driven by an ESP 300 motion controller (Newport Co., Irvine, CA). The firing rate of the laser was automatically adjusted by the laser handpiece to produce a specific density of lesions [18]. In the pulse energy range of 8-20 mJ, we encountered a 17 AE 4% discrepancy between set (value on user interface) and measured pulse energy.…”

Section: Methodsmentioning

confidence: 99%

“…The lesion dimensions were measured with a proprietary Visual Basic computer program (Reliant Technologies, Inc.) [18]. The lesion dimension represents the maximum depth and width of the ablated cavity plus the outermost border of the coagulation or viability zone histologically determined by H&E or LDH staining, respectively.…”

Section: Methodsmentioning

confidence: 99%

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Ex vivo histological characterization of a novel ablative fractional resurfacing device

et al. 2006

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Background and Objectives: We introduce a novel CO 2 laser device that utilizes ablative fractional resurfacing for deep dermal tissue removal and characterize the resultant thermal effects in skin. Study Design/Materials and Methods: A prototype 30 W, 10.6 mm CO 2 laser was focused to a 1/e 2 spot size of 120 mm and pulse duration up to 0.7 milliseconds to achieve a microarray pattern in ex vivo human skin. Lesion depth and width were assessed histologically using either hematoxylin & eosin (H&E) or lactate dehyrdogenase (LDH) stain. Pulse energies were varied to determine their effect on lesion dimensions. Results: Microarrays of ablative and thermal injury were created in fresh ex vivo human skin irradiated with the prototype CO 2 laser device. Zones of tissue ablation were surrounded by areas of tissue coagulation spanning the epidermis and part of the dermis. A thin condensed lining on the interior wall of the lesion cavity was observed consistent with eschar formation. At 23.3 mJ, the lesion width was approximately 350 mm and depth 1 mm. In this configuration, the cavities were spaced approximately 500 mm apart and interlesional epidermis and dermis demonstrated viable tissue by LDH staining. Conclusion: A novel prototype ablative CO 2 laser device operating in a fractional mode was developed and its resultant thermal effects in human abdominal tissue were characterized. We discovered that controlled microarray patterns could be deposited in skin with variable depths of dermal tissue ablation depending on the treatment pulse energy. This is the first report to characterize the successful use of ablative fractional resurfacing as a potential approach to dermatological treatment. Lasers Surg. Med. 39:87-95, 2007. ß

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Ex vivo histological characterization of a novel ablative fractional resurfacing device

et al. 2006

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“…Minimal side effects, downtime and superior results were all demonstrated in multiple previous studies. 12,13 This study was designed to assess and compare the effectiveness of fractional CO 2 laser and fractional non-ablative 1540 nm erbium doped glass laser in the treatment of atrophic acne scars in Egyptian patients. We aimed to investigate the safety of the treatments as well as patients satisfaction following treatment as well.…”

Section: Discussionmentioning

confidence: 99%

Ablative Fractional 10 600 nm Carbon Dioxide Laser Versus Non-ablative Fractional 1540 nm Erbium-Glass Laser in Egyptian Post-acne Scar patients

2017

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Introduction: Non-ablative fractional erbium-doped glass 1540 nm and fractional ablative 10600 nm carbon dioxide lasers are regarded as effective modalities for treating acne atrophic scars. In this study, we aimed to compare the effectiveness of fractional CO2 laser and fractional nonablative 1540 nm erbium doped glass laser in treating post acne atrophic scars in Egyptian patients. Methods: Fifty-eight patients complaining of moderate and severe acne atrophic scars were randomly divided into 2 groups of 29 patients each. Both groups were subjected to 4 treatment sessions with 3 weeks interval and were followed up for 3 months. In group A, enrolled patients received CO2 laser, while in group B, patients were treated with 1540 nm erbium glass fractional laser. Results: Clinical assessment revealed that the mean grades of progress and improvement were higher with fractional 10600 nm CO2 laser but with non-significant difference between both treatments (P = 0.1). The overall patients' satisfaction with both lasers were not significantly different (P = 0.44). Conclusion: Both fractional ablative CO2 and fractional non-ablative erbium glass lasers are good modalities for treating acne scars with a high efficacy and safety profile and good patient satisfaction. The fractional ablative laser showed higher efficacy while non-ablative laser offered less pain and shorter downtime.

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“…As a result, fractional photothermolysis [50] and fractional resurfacing [51] became the best solutions for resurfacing and dermal remodeling while offering a comfortable treatment modality with a low side-effects profile. Fractional photothermolysis and resurfacing produce microscopic thermal zones (In the ablative mode, termed microscopic treatment zones) or MTZs that -can be delivered very rapidly depending on the enabling technologies.…”

Section: Trends and Future Direction Of Lasers In Dermatologymentioning

confidence: 99%

The Advent of Laser Therapies in Dermatology and Urology: Underlying Mechanisms, Recent Trends and Future Directions

Lee

Jeong

Chan³

2009

Journal of the Optical Society of Korea

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Following their applications in cardiology, ophthalmology and dentistry among others, the advent of lasers in dermatology and urology had become the success story of the past decade. Laser-assisted treatments in dermatology and urology are mainly based on the laser-induced tissue injury/coagulation and/or ablation, depending upon the desirable clinical endpoint. In this review, we discussed the underlying mechanisms of the laser induced tissue ablation. In any medical laser application, the controlled thermal injury and coagulation, and the extent of ablation, if required, are critical. The laser thermal mechanism of injury is intricately related to the selective absorption of light and its exposure duration, similarly to the laser induced ablation. The laser ablation mechanisms were categorized into four different categories (the photo-thermally induced ablation, the photo-mechanically induced ablation, the plasma induced ablation and the photoablation) and their fundamentals are herein described. The brief history of laser treatment modality in dermatology and urology are summarized.

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The effects of pulse energy variations on the dimensions of microscopic thermal treatment zones in nonablative fractional resurfacing

Cited by 76 publications

References 15 publications

Ex vivo histological characterization of a novel ablative fractional resurfacing device

Ex vivo histological characterization of a novel ablative fractional resurfacing device

Ablative Fractional 10 600 nm Carbon Dioxide Laser Versus Non-ablative Fractional 1540 nm Erbium-Glass Laser in Egyptian Post-acne Scar patients

The Advent of Laser Therapies in Dermatology and Urology: Underlying Mechanisms, Recent Trends and Future Directions

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