Enhanced uptake and photoactivation of topical methyl aminolevulinate after fractional CO2 laser pretreatment

M Haedersdal; J Katsnelson; F H Sakamoto; W A Farinelli; A G Doukas; J Tam; R R Anderson

doi:10.1002/lsm.21096

Enhanced uptake and photoactivation of topical methyl aminolevulinate after fractional CO2 laser pretreatment

M Haedersdal, J Katsnelson, F H Sakamoto, W A Farinelli, A G Doukas, J Tam, R R Anderson

85 Citations (Scopus)

Abstract

Background and Objectives Photodynamic therapy (PDT) of thick skin lesions is limited by topical drug uptake. Ablative fractional resurfacing (AFR) creates vertical channels that may facilitate topical PDT drug penetration and improve PDT-response in deep skin layers. The purpose of this study was to evaluate whether pre-treating the skin with AFR before topically applied methyl aminolevulinate (MAL) could enable a deep PDT-response. Materials and Methods Yorkshire swine were treated under general anesthesia with a fractional CO ₂ laser using stacked single pulses of 3milliseconds, 91.6mJ per pulse and subsequent topical MAL application for 3hours (Metvix®). Red light (LED arrays) was then delivered at fluences of 37 and 200J/cm ². Fluorescent photography and microscopy was used to quantify MAL-induced porphyrin distribution and PDT-induced photobleaching at the skin surface and five specific depths down to 1,800μm. Results Laser-ablated channels were approximately 1,850μm deep, which significantly increased topical MAL-induced porphyrin fluorescence (hair follicles, dermis, P<0.0001) and PDT response, both superficially and deep, versus topical MAL application alone. The fraction of porphyrin fluorescence lost by photobleaching was slightly less after 37J/cm ² than after 200J/cm ² (overall median values 67-90%; 37 vs. 200J/cm ², P>0.05 for all but one comparison). Photobleaching was steady throughout skin layers and did not vary significantly with skin depth at either LED fluence (P>0.05). Conclusions AFR greatly facilitates topical MAL-induced porphyrins and the fraction of photobleached porphyrins is similar for superficial and deep skin. These observations are consistent with AFR-enhanced uptake of MAL, increased porphyrin synthesis, and photodynamic activation of deep porphyrins even at the lower fluence of 37J/cm ², widely used in clinical practice. AFR appears to be a clinically practical means for improving PDT deep into the skin. Clinical studies are suggested to evaluate selectivity in targeting dysplastic cell types.

Original language	English
Journal	Lasers in Surgery and Medicine
Volume	43
Issue number	8
Pages (from-to)	804-13
Number of pages	10
ISSN	0196-8092
DOIs	https://doi.org/10.1002/lsm.21096
Publication status	Published - Sept 2011

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10.1002/lsm.21096

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@article{47bee9abca1e4ce78dc7a25e9f3134c1,

title = "Enhanced uptake and photoactivation of topical methyl aminolevulinate after fractional CO2 laser pretreatment",

abstract = "Background and Objectives Photodynamic therapy (PDT) of thick skin lesions is limited by topical drug uptake. Ablative fractional resurfacing (AFR) creates vertical channels that may facilitate topical PDT drug penetration and improve PDT-response in deep skin layers. The purpose of this study was to evaluate whether pre-treating the skin with AFR before topically applied methyl aminolevulinate (MAL) could enable a deep PDT-response. Materials and Methods Yorkshire swine were treated under general anesthesia with a fractional CO 2 laser using stacked single pulses of 3milliseconds, 91.6mJ per pulse and subsequent topical MAL application for 3hours (Metvix{\textregistered}). Red light (LED arrays) was then delivered at fluences of 37 and 200J/cm 2. Fluorescent photography and microscopy was used to quantify MAL-induced porphyrin distribution and PDT-induced photobleaching at the skin surface and five specific depths down to 1,800μm. Results Laser-ablated channels were approximately 1,850μm deep, which significantly increased topical MAL-induced porphyrin fluorescence (hair follicles, dermis, P<0.0001) and PDT response, both superficially and deep, versus topical MAL application alone. The fraction of porphyrin fluorescence lost by photobleaching was slightly less after 37J/cm 2 than after 200J/cm 2 (overall median values 67-90%; 37 vs. 200J/cm 2, P>0.05 for all but one comparison). Photobleaching was steady throughout skin layers and did not vary significantly with skin depth at either LED fluence (P>0.05). Conclusions AFR greatly facilitates topical MAL-induced porphyrins and the fraction of photobleached porphyrins is similar for superficial and deep skin. These observations are consistent with AFR-enhanced uptake of MAL, increased porphyrin synthesis, and photodynamic activation of deep porphyrins even at the lower fluence of 37J/cm 2, widely used in clinical practice. AFR appears to be a clinically practical means for improving PDT deep into the skin. Clinical studies are suggested to evaluate selectivity in targeting dysplastic cell types.",

author = "M Haedersdal and J Katsnelson and Sakamoto, {F H} and Farinelli, {W A} and Doukas, {A G} and J Tam and Anderson, {R R}",

note = "Copyright {\textcopyright} 2011 Wiley-Liss, Inc.",

year = "2011",

month = sep,

doi = "10.1002/lsm.21096",

language = "English",

volume = "43",

pages = "804--13",

journal = "Lasers in Surgery and Medicine",

issn = "0196-8092",

publisher = "JohnWiley & Sons, Inc.",

number = "8",

}

TY - JOUR

T1 - Enhanced uptake and photoactivation of topical methyl aminolevulinate after fractional CO2 laser pretreatment

AU - Haedersdal, M

AU - Katsnelson, J

AU - Sakamoto, F H

AU - Farinelli, W A

AU - Doukas, A G

AU - Tam, J

AU - Anderson, R R

PY - 2011/9

Y1 - 2011/9

N2 - Background and Objectives Photodynamic therapy (PDT) of thick skin lesions is limited by topical drug uptake. Ablative fractional resurfacing (AFR) creates vertical channels that may facilitate topical PDT drug penetration and improve PDT-response in deep skin layers. The purpose of this study was to evaluate whether pre-treating the skin with AFR before topically applied methyl aminolevulinate (MAL) could enable a deep PDT-response. Materials and Methods Yorkshire swine were treated under general anesthesia with a fractional CO 2 laser using stacked single pulses of 3milliseconds, 91.6mJ per pulse and subsequent topical MAL application for 3hours (Metvix®). Red light (LED arrays) was then delivered at fluences of 37 and 200J/cm 2. Fluorescent photography and microscopy was used to quantify MAL-induced porphyrin distribution and PDT-induced photobleaching at the skin surface and five specific depths down to 1,800μm. Results Laser-ablated channels were approximately 1,850μm deep, which significantly increased topical MAL-induced porphyrin fluorescence (hair follicles, dermis, P<0.0001) and PDT response, both superficially and deep, versus topical MAL application alone. The fraction of porphyrin fluorescence lost by photobleaching was slightly less after 37J/cm 2 than after 200J/cm 2 (overall median values 67-90%; 37 vs. 200J/cm 2, P>0.05 for all but one comparison). Photobleaching was steady throughout skin layers and did not vary significantly with skin depth at either LED fluence (P>0.05). Conclusions AFR greatly facilitates topical MAL-induced porphyrins and the fraction of photobleached porphyrins is similar for superficial and deep skin. These observations are consistent with AFR-enhanced uptake of MAL, increased porphyrin synthesis, and photodynamic activation of deep porphyrins even at the lower fluence of 37J/cm 2, widely used in clinical practice. AFR appears to be a clinically practical means for improving PDT deep into the skin. Clinical studies are suggested to evaluate selectivity in targeting dysplastic cell types.

AB - Background and Objectives Photodynamic therapy (PDT) of thick skin lesions is limited by topical drug uptake. Ablative fractional resurfacing (AFR) creates vertical channels that may facilitate topical PDT drug penetration and improve PDT-response in deep skin layers. The purpose of this study was to evaluate whether pre-treating the skin with AFR before topically applied methyl aminolevulinate (MAL) could enable a deep PDT-response. Materials and Methods Yorkshire swine were treated under general anesthesia with a fractional CO 2 laser using stacked single pulses of 3milliseconds, 91.6mJ per pulse and subsequent topical MAL application for 3hours (Metvix®). Red light (LED arrays) was then delivered at fluences of 37 and 200J/cm 2. Fluorescent photography and microscopy was used to quantify MAL-induced porphyrin distribution and PDT-induced photobleaching at the skin surface and five specific depths down to 1,800μm. Results Laser-ablated channels were approximately 1,850μm deep, which significantly increased topical MAL-induced porphyrin fluorescence (hair follicles, dermis, P<0.0001) and PDT response, both superficially and deep, versus topical MAL application alone. The fraction of porphyrin fluorescence lost by photobleaching was slightly less after 37J/cm 2 than after 200J/cm 2 (overall median values 67-90%; 37 vs. 200J/cm 2, P>0.05 for all but one comparison). Photobleaching was steady throughout skin layers and did not vary significantly with skin depth at either LED fluence (P>0.05). Conclusions AFR greatly facilitates topical MAL-induced porphyrins and the fraction of photobleached porphyrins is similar for superficial and deep skin. These observations are consistent with AFR-enhanced uptake of MAL, increased porphyrin synthesis, and photodynamic activation of deep porphyrins even at the lower fluence of 37J/cm 2, widely used in clinical practice. AFR appears to be a clinically practical means for improving PDT deep into the skin. Clinical studies are suggested to evaluate selectivity in targeting dysplastic cell types.

U2 - 10.1002/lsm.21096

DO - 10.1002/lsm.21096

M3 - Journal article

SN - 0196-8092

VL - 43

SP - 804

EP - 813

JO - Lasers in Surgery and Medicine

JF - Lasers in Surgery and Medicine

IS - 8

ER -

Enhanced uptake and photoactivation of topical methyl aminolevulinate after fractional CO2 laser pretreatment

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