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Journal Article
Research Support, Non-U.S. Gov't
Needle-free cutaneous delivery of living human cells by Er:YAG fractional laser ablation.
Expert Opinion on Drug Delivery 2018 June
BACKGROUND: Dermatological diseases, including most skin cancers and rare genetic conditions frequently originate in the epidermis. Targeted, topical cell-based therapy is a promising therapeutic strategy. Here, we present the first report demonstrating that fractional laser ablation enables local 'needle-free' intraepidermal delivery of living human cells.
METHODS: The cells penetrated porcine ear skin via microchannels created by Er:YAG fractional laser ablation; cell delivery was quantified using a haemocytometer. Cutaneous distribution was confirmed visually by laser scanning confocal microscopy and histological analysis.
RESULTS: Total cell delivery (sum of amounts permeated and deposited) after 24 h increased from 5.7 ± 0.1 x105 to 9.6 ± 1.6 x105 cells/cm2 when increasing pore density from 300 to 600 pores/cm2 , - corresponding to 19- and 32-fold increases over the control. At 600 pores/cm2 , cell deposition was 136-fold greater than cell permeation - the latter most likely due to transport from micropores into appendageal pathways. Production of GFP post-delivery confirmed cell remained viability.
CONCLUSION: The results demonstrate the feasibility of using controlled laser microporation to achieve local 'needle-free' cutaneous delivery of living human cells to the epidermis and dermis. This raises the possibility of using this technique for targeted new approaches for dermatological therapy in these regions.
METHODS: The cells penetrated porcine ear skin via microchannels created by Er:YAG fractional laser ablation; cell delivery was quantified using a haemocytometer. Cutaneous distribution was confirmed visually by laser scanning confocal microscopy and histological analysis.
RESULTS: Total cell delivery (sum of amounts permeated and deposited) after 24 h increased from 5.7 ± 0.1 x105 to 9.6 ± 1.6 x105 cells/cm2 when increasing pore density from 300 to 600 pores/cm2 , - corresponding to 19- and 32-fold increases over the control. At 600 pores/cm2 , cell deposition was 136-fold greater than cell permeation - the latter most likely due to transport from micropores into appendageal pathways. Production of GFP post-delivery confirmed cell remained viability.
CONCLUSION: The results demonstrate the feasibility of using controlled laser microporation to achieve local 'needle-free' cutaneous delivery of living human cells to the epidermis and dermis. This raises the possibility of using this technique for targeted new approaches for dermatological therapy in these regions.
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