Hereditary epidermolysis bullosa (EB) is a rare mutilating and lethal single-gene genodermatosis, and places a heavy burden on society and families. Cell therapy has become a very promising method for the treatment of EB due to its excellent and stable clinical efficacy. This review summarizes progress in laboratory research and clinical application of stem cell- and somatic cell-based therapies in EB in recent years.

Objective To explore the effect of platelet-rich plasma (PRP) on the generation of reactive oxygen species (ROS) and the phenotypes of photo-aging fibroblasts.Methods A photoaging cell model by repeating UVB irradiation was treated using appropriate concentration of PRP;Cell morphology and the rate of aging dying were observed under inverted microscope 24 hours later after establishment of the cell model;The expression of ROS between experimental and control group was detected using fluorescence microscope after single UVB irradiation.The relative intensity of fluorescence was analyzed using flow cytometry.Results PRP could ameliorate the large and sprawl appearance of photoaging fibroblasts obviously,reduce the generation of ROS as well as decrease the relative intensity of ROS.Conclusions PRP can decrease the level of intracellular oxidative stress caused by UVB irradiation,reduce the generation of ROS and ameliorate the senescence-like phenotypes of pho toaging fibroblasts.

BACKGROUND: Some scholars have found that dermal papilla spheroid–derived exosomes could promote the development of hair follicles. However, whether adipose-derived stem cell exosomes (ADSC-Exos) have a similar effect on hair growth has not been determined yet. Thus, the purpose of this article was to detect whether ADSC-Exos could promote hair regeneration. METHODS: Adipose-derived stem cells (ADSCs) were isolated from 6-week-old C57BL/6 mice. Then, ADSC-Exos were isolated from the ADSCs. Western blotting was used to detect specific exosome markers. The particle size and distribution of the exosomes were analyzed by NanoSight dynamic light scattering. A total of 12 nude mice were randomly divided into two groups (n = 6 each): the ADSC-Exos group and the control group. For the control group, a mixture of freshly isolated dermal cells (DCs) and epidermal cells (ECs) was grafted. For the ADSC-Exos group, a mixture of DCs, ECs, and 50 lg/ml of ADSC-Exos was grafted. Gross evaluation of the hair regeneration was carried out 2–3 weeks after the transplantation, and the graft site was harvested for histology at the third week. Results: The existence of exosomes derived from ADSCs was evidenced by CD63, ALX1, and CD9 expression. Two or three weeks after the grafting, the number of regenerated hairs in the ADSC-Exos group was higher than that in the control group (p < 0.001). Histologically, the terminal hairs were remarkable in the ADSC-Exos group, whereas the hair follicles observed in the control group were comparatively immature. The ADSC-Exos group had a higher number of regenerated follicles than the control group (p < 0.001). In addition, we found that the skin tissues in the ADSC-Exos group had higher PDGF and vascular endothelial growth factor expressions and lower transforming growth factor beta 1 levels than those in the control group CONCLUSION Our results indicated that ADSC-Exos could promote in vivo hair follicle regeneration.

BACKGROUND: Some scholars have found that dermal papilla spheroid–derived exosomes could promote the development of hair follicles. However, whether adipose-derived stem cell exosomes (ADSC-Exos) have a similar effect on hair growth has not been determined yet. Thus, the purpose of this article was to detect whether ADSC-Exos could promote hair regeneration. METHODS: Adipose-derived stem cells (ADSCs) were isolated from 6-week-old C57BL/6 mice. Then, ADSC-Exos were isolated from the ADSCs. Western blotting was used to detect specific exosome markers. The particle size and distribution of the exosomes were analyzed by NanoSight dynamic light scattering. A total of 12 nude mice were randomly divided into two groups (n = 6 each): the ADSC-Exos group and the control group. For the control group, a mixture of freshly isolated dermal cells (DCs) and epidermal cells (ECs) was grafted. For the ADSC-Exos group, a mixture of DCs, ECs, and 50 lg/ml of ADSC-Exos was grafted. Gross evaluation of the hair regeneration was carried out 2–3 weeks after the transplantation, and the graft site was harvested for histology at the third week. Results: The existence of exosomes derived from ADSCs was evidenced by CD63, ALX1, and CD9 expression. Two or three weeks after the grafting, the number of regenerated hairs in the ADSC-Exos group was higher than that in the control group (p < 0.001). Histologically, the terminal hairs were remarkable in the ADSC-Exos group, whereas the hair follicles observed in the control group were comparatively immature. The ADSC-Exos group had a higher number of regenerated follicles than the control group (p < 0.001). In addition, we found that the skin tissues in the ADSC-Exos group had higher PDGF and vascular endothelial growth factor expressions and lower transforming growth factor beta 1 levels than those in the control group CONCLUSION Our results indicated that ADSC-Exos could promote in vivo hair follicle regeneration.