A novel cell-containing device for regenerative medicine: biodegradable nonwoven filters with peripheral blood cells promote wound healing.

The efficacy of skin regeneration devices consisting of nonwoven filters and peripheral blood cells was investigated for wound healing. We previously found that human peripheral blood cells enhanced their production of growth factors, such as transforming growth factor ß1 (TGF-ß1) and vascular endothelial growth factor, when they were captured on nonwoven filters. Cells on biodegradable filters were expected to serve as a local supply of growth factors and cell sources when they were placed in wounded skin. Nonwoven filters made of biodegradable polylactic acid (PLA) were cut out as 13-mm disks and placed into cell-capturing devices. Mouse peripheral blood was filtered, resulting in PLA filters with mouse peripheral blood cells (m-PBCs) at capture rates of 65.8 ± 5.2%. Then, the filters were attached to full-thickness surgical wounds in a diabetic db/db mouse skin for 14 days as a model of severe chronic wounds. The wound area treated with PLA nonwoven filters with m-PBCs (PLA/B+) was reduced to 8.5 ± 12.2% when compared with day 0, although the non-treated control wounds showed reduction only to 60.6 ± 27.8%. However, the PLA filters without m-PBCs increased the wound area to 162.9 ± 118.7%. By histopathological study, the PLA/B+ groups more effectively accelerated formation of epithelium. The m-PBCs captured on the PLA filters enhanced keratinocyte growth factor (FGF-7) and TGF-ß1 productions in vitro, which may be related to wound healing. This device is useful for regeneration of wounded skin and may be adaptable for another application.

Appropriate nonwoven filters effectively capture human peripheral blood cells and mesenchymal stem cells, which show enhanced production of growth factors.

Scaffolds, growth factors, and cells are three essential components in regenerative medicine. Nonwoven filters, which capture cells, provide a scaffold that localizes and concentrates cells near injured tissues. Further, the cells captured on the filters are expected to serve as a local supply of growth factors. In this study, we investigated the growth factors produced by cells captured on nonwoven filters. Nonwoven filters made of polyethylene terephthalate (PET), biodegradable polylactic acid (PLA), or chitin (1.2-22 µm fiber diameter) were cut out as 13 mm disks and placed into cell-capturing devices. Human mesenchymal stem cells derived from adipose tissues (h-ASCs) and peripheral blood cells (h-PBCs) were captured on the filter and cultured to evaluate growth factor production. The cell-capture rates strongly depended on the fiber diameter and the number of filter disks. Nonwoven filter disks were composed of PET or PLA fibers with fiber diameters of 1.2-1.8 µm captured over 70% of leukocytes or 90% of h-ASCs added. The production of vascular endothelial growth factor (VEGF), transforming growth factor ß1, and platelet-derived growth factor AB were significantly enhanced by the h-PBCs captured on PET or PLA filters. h-ASCs on PLA filters showed significantly enhanced production of VEGF. These enhancements varied with the combination of the nonwoven filter and cells. Because of the enhanced growth factor production, the proliferation of human fibroblasts increased in conditioned medium from h-PBCs on PET filters. This device consisting of nonwoven filters and cells should be investigated further for possible use in the regeneration of impaired tissues.

Fabrication of mouse embryonic stem cell-derived layered cardiac cell sheets using a bioreactor culture system.

Bioengineered functional cardiac tissue is expected to contribute to the repair of injured heart tissue. We previously developed cardiac cell sheets using mouse embryonic stem (mES) cell-derived cardiomyocytes, a system to generate an appropriate number of cardiomyocytes derived from ES cells and the underlying mechanisms remain elusive. In the present study, we established a cultivation system with suitable conditions for expansion and cardiac differentiation of mES cells by embryoid body formation using a three-dimensional bioreactor. Daily conventional medium exchanges failed to prevent lactate accumulation and pH decreases in the medium, which led to insufficient cell expansion and cardiac differentiation. Conversely, a continuous perfusion system maintained the lactate concentration and pH stability as well as increased the cell number by up to 300-fold of the seeding cell number and promoted cardiac differentiation after 10 days of differentiation. After a further 8 days of cultivation together with a purification step, around 1 × 10(8) cardiomyocytes were collected in a 1-L bioreactor culture, and additional treatment with noggin and granulocyte colony stimulating factor increased the number of cardiomyocytes to around 5.5 × 10(8). Co-culture of mES cell-derived cardiomyocytes with an appropriate number of primary cultured fibroblasts on temperature-responsive culture dishes enabled the formation of cardiac cell sheets and created layered-dense cardiac tissue. These findings suggest that this bioreactor system with appropriate medium might be capable of preparing cardiomyocytes for cell sheet-based cardiac tissue.