Efficacy of Gelatin Hydrogel Impregnated With Concentrated Platelet Lysate in Murine Wound Healing.

BACKGROUND: The efficacy of a gelatin hydrogel (GH) sheet impregnated with platelet-rich plasma in full-thickness wound healing has been reported. Human platelet lysate is another potential natural product for use in wound healing. The present study examined the effects of a GH sheet impregnated with concentrated freeze-dried platelet lysate on wound healing after storage for 9 mo. MATERIALS AND METHODS: Platelet concentrates were subjected to three freeze-thaw cycles and freeze-dried then preserved at 4°C. Reconstitution with saline was then performed to produce 1-fold (hPL1), 2-fold (hPL2), and 3-fold (hPL3) concentrations of preserved platelet lysate. Full-thickness wounds were made on the back of male C57Bl6J/Jcl mice. Wounds were treated with saline, hPL1, or a GH sheet impregnated with saline, hPL1, hPL2, or hPL3. Histologic examinations using hematoxylin-eosin, Azan, and anti-CD31 staining were performed on days 4, 7, and 14 to assess neoepithelialization and granulation tissue and capillary formation. RESULTS: This study showed that the GH sheet itself or the simple administration of hPL1 did not accelerate the healing process. However, the GH sheet impregnated with hPL1 accelerated the granulation tissue formation to some extent, and the GH sheet impregnated with hPL2 or hPL3 clearly accelerated the capillary formation and the granulation tissue formation. In addition, the GH sheet impregnated with hPL3 had the longest epithelium formation. CONCLUSIONS: A GH sheet impregnated with long-term preserved 2-fold or 3-fold concentrated platelet lysate enhances the wound healing process.

Ex vivo Induction of Apoptotic Mesenchymal Stem Cell by High Hydrostatic Pressure.

Among promising solutions for tissue repair and wound healing, mesenchymal stem (or stromal) cells (MSCs) have been a focus of attention and have become the most clinically studied experimental cell therapy. Recent studies reported the importance of apoptosis in MSC-mediated immunomodulation, in which apoptotic MSCs (apoMSCs) were shown to be superior to living MSCs. Nowadays, high hydrostatic pressure (HHP), a physical technique that uses only fluid pressure, has been developed and applied in various bioscience fields, including biotechnology, biomaterials, and regenerative medicine, as its safe and simply operation. In the current study, we investigated the impact of HHP treatment on human bone marrow-MSC survival and proliferation. Based on the detection of executioner caspase activation, phosphatidylserine exposure, DNA fragmentation (TUNEL) and irrefutable ultrastructural morphological changes on transmission electron microscopy (TEM), our data revealed that HHP treatment induced complete apoptosis in MSCs. Notably, this technique might provide manipulated products for use in cell-based therapies as manufacturing capability expands. We hope that our findings will contribute to the improvement of MSCs or EVs in translational research development. Graphical Abstract.

High Hydrostatic Pressure Therapy Annihilates Squamous Cell Carcinoma in a Murine Model.

Cutaneous squamous cell carcinoma (cSCC) is one of the most common skin cancers. In the treatment of cSCC, it is necessary to remove it completely, and reconstructive surgery, such as a skin graft or a local or free flap, will be required, depending on the size, with donor-site morbidity posing a burden to the patient. The high hydrostatic pressure (HHP) technique has been developed as a physical method of decellularizing various tissues. We previously reported that HHP at 200 MPa for 10 min could inactivate all cells in the giant congenital melanocytic nevus, and we have already started a clinical trial using this technique. In the present study, we explored the critical pressurization condition for annihilating cSCC cells in vitro and confirmed that this condition could also annihilate cSCC in vivo. We prepared 5 pressurization conditions in this study (150, 160, 170, 180, and 190 MPa for 10 min) and confirmed that cSCC cells were killed by pressurization at ≥160 MPa for 10 min. In the in vivo study, the cSCC cells inactivated by HHP at 200 MPa for 10 min were unable to proliferate after injection into the intradermal space of mice, and transplanted cSCC tissues that had been inactivated by HHP showed a decreased weight at 5 weeks after implantation. These results suggested that HHP at 200 MPa for 10 min was able to annihilate SCC, so HHP technology may be a novel treatment of skin cancer.

A comparison of the wound healing process after the application of three dermal substitutes with or without basic fibroblast growth factor impregnation in diabetic mice.

Pelnac GplusⓇ, IntegraⓇ, and TerudermisⓇ are approved artificial dermis products in Japan. Previously, we proved that Pelnac GplusⓇ was able to sustain basic fibroblast growth factor (bFGF) and accelerated wound healing by releasing impregnated bFGF. In this study, we impregnated Pelnac GplusⓇ, IntegraⓇ, and TerudermisⓇ with bFGF and compared the binding activity and wound-healing process. We applied bFGF to each material and compared the bFGF concentrations in the surrounding area after 24-h incubation. For the in vivo study, dermal substitutes were impregnated with bFGF and implanted into full-thickness wounds of BKS.Cg-+Leprdb/+Leprdb/Jcl mice. Wounds were evaluated at days 7, 14, and 21 after implantation. The in vitro study showed that bFGF is strongly bound to IntegraⓇ, followed by Pelnac GplusⓇ and TerudermisⓇ. The in vivo study showed that fibroblasts and capillaries had infiltrated into the Pelnac GplusⓇ but not the IntegraⓇ or TerudermisⓇ. Furthermore, long epithelium and wide granulation tissue were formed in the Pelnac GplusⓇ with bFGF group. The TerudermisⓇ with bFGF group had more capillaries than other groups, but only at the base of the wound. The combination of Pelnac GplusⓇ with bFGF may be a novel approach for treating full-thickness skin defects or chronic skin ulcers.

Exploration of the Pressurization Condition for Killing Human Skin Cells and Skin Tumor Cells by High Hydrostatic Pressure.

High hydrostatic pressure (HHP) is a physical method for inactivating cells or tissues without using chemicals such as detergents. We previously reported that HHP at 200 MPa for 10 min was able to inactivate all cells in skin and giant congenital melanocytic nevus (GCMN) without damaging the extracellular matrix. We also reported that HHP at 150 MPa for 10 min was not sufficient to inactivate them completely, while HHP at 200 MPa for 10 min was able to inactivate them completely. We intend to apply HHP to treat malignant skin tumor as the next step; however, the conditions necessary to kill each kind of cell have not been explored. In this work, we have performed a detailed experimental study on the critical pressure and pressurization time using five kinds of human skin cells and skin tumor cells, including keratinocytes (HEKas), dermal fibroblasts (HDFas), adipose tissue-derived stem cells (ASCs), epidermal melanocytes (HEMa-LPs), and malignant melanoma cells (MMs), using pressures between 150 and 200 MPa. We pressurized cells at 150, 160, 170, 180, or 190 MPa for 1 s, 2 min, and 10 min and evaluated the cellular activity using live/dead staining and proliferation assays. The proliferation assay revealed that HEKas were inactivated at a pressure higher than 150 MPa and a time period longer than 2 min, HDFas and MMs were inactivated at a pressure higher than 160 MPa and for 10 min, and ASCs and HEMa-LPs were inactivated at a pressure higher than 150 MPa and for 10 min. However, some HEMa-LPs were observed alive after HHP at 170 MPa for 10 min, so we concluded that HHP at a pressure higher than 180 MPa for 10 min was able to inactivate five kinds of cells completely.

Hydrostatic pressure can induce apoptosis of the skin.

We previously showed that high hydrostatic pressure (HHP) treatment at 200 MPa for 10 min induced complete cell death in skin and skin tumors via necrosis. We used this technique to treat a giant congenital melanocytic nevus and reused the inactivated nevus tissue as a dermis autograft. However, skin inactivated by HHP promoted inflammation in a preclinical study using a porcine model. Therefore, in the present study, we explored the pressurization conditions that induce apoptosis of the skin, as apoptotic cells are not believed to promote inflammation, so the engraftment of inactivated skin should be improved. Using a human dermal fibroblast cell line in suspension culture, we found that HHP at 50 MPa for ≥ 36 h completely induced fibroblast cell death via apoptosis based on the morphological changes in transmission electron microscopy, reactive oxygen species elevation, caspase activation and phosphatidylserine membrane translocation. Furthermore, immunohistochemistry with terminal deoxynucleotidyl transferase dUTP nick-end labeling and cleaved caspase-3 showed most cells in the skin inactivated by pressurization to be apoptotic. Consequently, in vivo grafting of apoptosis-induced inactivated skin resulted in successful engraftment and greater dermal cellular density and macrophage infiltration than our existing method. Our finding supports an alternative approach to hydrostatic pressure application.

The sustained release of basic fibroblast growth factor accelerates angiogenesis and the engraftment of the inactivated dermis by high hydrostatic pressure.

We developed a novel skin regeneration therapy combining nevus tissue inactivated by high hydrostatic pressure (HHP) in the reconstruction of the dermis with a cultured epidermal autograft (CEA). The issue with this treatment is the unstable survival of CEA on the inactivated dermis. In this study, we applied collagen/gelatin sponge (CGS), which can sustain the release of basic fibroblast growth factor (bFGF), to the inactivated skin in order to accelerate angiogenesis. Murine skin grafts from C57BL6J/Jcl mice (8 mm in diameter) were prepared, inactivated by HHP and cryopreserved. One month later, the grafts were transplanted subcutaneously onto the back of other mice and covered by CGS impregnated with saline or bFGF. Grafts were harvested after one, two and eight weeks, at which point the engraftment was evaluated through the histology and angiogenesis-related gene expressions were determined by real-time polymerase chain reaction. Histological sections showed that the dermal cellular density and newly formed capillaries in the bFGF group were significantly higher than in the control group. The relative expression of FGF-2, PDGF-A and VEGF-A genes in the bFGF group was significantly higher than in the control group at Week 1. This study suggested that the angiogenesis into grafts was accelerated, which might improve the engraftment of inactivated dermis in combination with the sustained release of bFGF by CGSs.

Comparison of the efficacy of cryopreserved human platelet lysate and refrigerated lyophilized human platelet lysate for wound healing.

INTRODUCTION: Human platelet lysate (hPL) part of the growth factor cocktail derived from human platelets, which has been applied as a cell growth supplement. The production process is easier in comparison to platelet-rich plasma; thus, hPL is now considered for use in wound healing therapy. However, methods for preserving hPL for more than several months that maintain its bioactivity must be considered, especially for chronic wound treatment. The present study compared the effects of preservation for 9 months using a refrigerator or deep freezer. METHODS: We investigated three preservation conditions. In the C-hPL group, hPL was stored at -80 °C in a deep freezer for 9 months; in the CL-hPL group, hPL was cryopreserved for 9 months at -80 °C in a deep freezer then lyophilized; in the L-hPL group, lyophilized hPL was refrigerated at 4 °C for 9 months. The quantity and quality of growth factors in these three groups were measured by an ELISA and in fibroblast cell cultures. Then, gelatin hydrogel discs were impregnated with hPL and its effects with regard to the promotion of wound healing in mice were evaluated by histologic examinations. RESULTS: The PDGF-BB concentration in C-hPL, CL-hPL and L-hPL was 18,363 ± 370 pg/ml, 11,325 ± 171 pg/ml, and 12,307 ± 348 pg/ml, respectively; the VEGF concentration was 655 ± 23 pg/ml, 454 ± 27 pg/ml, and 499 ± 23 pg/ml, respectively; and the TGF-ß1 concentration was 97,363 ± 5418 pg/ml, 73,198 ± 2442 pg/ml, and 78,034 ± 3885 pg/ml, respectively. In cell culture medium, fibroblast cell cultures were better supported in the hPL groups than in the fetal bovine serum group. In the histologic examination of the wound healing process, no differences were observed among the three preserved hPL groups with regard to epithelialization, or granulation tissue or capillary formation. The wounds in all groups had almost healed by day 14. CONCLUSIONS: The stability of growth factors contained in lyophilized hPL is maintained at 4 °C for up to 9 months. This was a versatile preservation method that can be applied in clinical practice.