The controlled release of small molecular modulators of the immune response from hydrogel microspheres (MS) used for cell immobilization is an attractive approach to reduce pericapsular fibrotic overgrowth (PFO) after transplantation. Ketoprofen is a well-known nonsteroidal anti-inflammatory drug involved in the early stage inflammation cascade. PEGylated derivatives of ketoprofen, presenting either ester or amide linkage to the drug, were synthesized and conjugated to the hydroxyl groups of sodium alginate (Na-alg). Functionalized cell-free and MIN6 cells containing MS were produced from the resulting modified alginates. In vitro quantification of ketoprofen release indicated regular and sustained drug delivery over 14 days, resulting from the hydrolytic cleavage of the ester bond. The release kinetics was enhanced over the initial 7 days by the presence of MIN6 cells, probably as a result of cell esterase activity. In the presence of amide bond, traces of ketoprofen were released over 14 days due to a much slower hydrolysis kinetics. Cell-free and MIN6 cells containing MS were transplanted in immune-competent mice, either in the peritoneal cavity or under the kidney capsule, with a follow-up period of 30 days. Comparison with nonmodified Ca-alg MS transplanted in the same conditions demonstrated a clear reduction in the severity of PFO for MS functionalized with ketoprofen. Quantification of collagen deposition on MIN6 cells containing MS transplanted under the kidney capsule revealed the significant effect of ketoprofen release to decrease fibrotic tissue formation. The impact was more pronounced when the drug was covalently conjugated by an ester linkage, allowing higher concentration of the anti-inflammatory compound to be delivered at the transplantation site. The functionality of microencapsulated MIN6 cells 30 days after transplantation was confirmed by detection of insulin positive cell content.
Encapsulated hepatocyte transplantation and encapsulated mesenchymal stem cell transplantation are newly developed potential treatments for acute and chronic liver diseases, respectively. Cells are microencapsulated in biocompatible semipermeable alginate-based hydrogels. Microspheres protect cells against antibodies and immune cells, while allowing nutrients, small/medium size proteins and drugs to diffuse inside and outside the polymer matrix. Microencapsulated cells are assessed in vitro and designed for experimental transplantation and for future clinical applications.Here, we describe the protocol for microencapsulation of hepatocytes and mesenchymal stem cells within hybrid poly(ethylene glycol)-alginate hydrogels.
Neonatal and juvenile porcine islet cell clusters (ICC) present an unlimited source for islet xenotransplantation to treat type 1 diabetes patients. We isolated ICC from pancreata of 14 days old juvenile piglets and characterized their maturation by immunofluorescence and insulin secretion assays. Multipotent mesenchymal stromal cells derived from exocrine tissue of same pancreata (pMSC) were characterized for their differentiation potential and ability to sustain ICC insulin secretion in vitro and in vivo. Isolation of ICC resulted in 142 ± 50 × 103 IEQ per pancreas. Immunofluorescence staining revealed increasing presence of insulin‐positive beta cells between day 9 and 21 in culture and insulin content per 500IEC of ICC increased progressively over time from 1178.4 ± 450 µg/L to 4479.7 ± 1954.2 µg/L from day 7 to 14, P < .001. Highest glucose‐induced insulin secretion by ICC was obtained at day 7 of culture and reached a fold increase of 2.9 ± 0.4 compared to basal. Expansion of adherent cells from the pig exocrine tissue resulted in a homogenous CD90+, CD34−, and CD45− fibroblast‐like cell population and differentiation into adipocytes and chondrocytes demonstrated their multipotency. Insulin release from ICC was increased in the presence of pMSC and dependent on cell‐cell contact (glucose‐induced fold increase: ICC alone: 1.6 ± 0.2; ICC + pMSC + contact: 3.2 ± 0.5, P = .0057; ICC + pMSC no‐contact: 1.9 ± 0.3; theophylline stimulation: alone: 5.4 ± 0.7; pMSC + contact: 8.4 ± 0.9, P = .013; pMSC no‐contact: 5.2 ± 0.7). After transplantation of encapsulated ICC using Ca2+‐alginate (alg) microcapsules into streptozotocin‐induced diabetic and immunocompetent mice, transient normalization of glycemia was obtained up to day 7 post‐transplant, whereas ICC co‐encapsulated with pMSC did not improve glycemia and showed increased pericapsular fibrosis. We conclude that pMSC derived from juvenile porcine exocrine pancreas improves insulin secretion of ICC by direct cell‐cell contact. For transplantation purposes, the use of pMSC to support beta‐cell function will depend on the development of new anti‐fibrotic polymers and/or on genetically modified pigs with lower immunogenicity.
Background Tolerogenic dendritic cells (DCs) represent a promising approach to promote transplantation tolerance. In this study, the potential of autologous bone marrow (BM)–derived murine DC to protect rat‐to‐mouse islets xenografts was analyzed. Methods Tolerogenic DCs were generated by differentiating BM cells in the presence of granulocyte‐macrophage colony‐stimulating factor and interleukin 10 (IL‐10, IL‐10 DC). The phenotype of IL‐10 DC was characterized in vitro by expression of costimulatory/inhibitory molecules (flow cytometry) and cytokines (Luminex and ELISA), their function by phagocytosis and T‐cell stimulation assays. To study transplant tolerance in vivo, rat islets were transplanted alone or in combination with autologous murine IL‐10 DC under the kidney capsule of streptozotocin‐induced diabetic C57BL/6 mice. Xenograft survival was evaluated by monitoring glycemia, cellular infiltration of xenografts by microscopy and flow cytometry 10 days post‐transplantation. Results Compared with control DC, IL‐10 DC exhibited lower levels of major histocompatibility complex class II, costimulatory molecules (CD40, CD86, CD205), lower production of pro‐inflammatory cytokines (IL‐12p70, TNF, IL‐6), and higher production of IL‐10. Phagocytosis of xenogeneic rat splenocytes was not impaired in IL‐10 DC, whereas stimulation of T‐cell proliferation was reduced in the presence of IL‐10 DC. Xenograft survival of rat islets in diabetic mice co‐transplanted with autologous murine IL‐10 DC was significantly prolonged from 12 to 21 days, without additional immunosuppressive treatment. Overall, infiltration of xenografts by T cells and myeloid cells was not different in IL‐10 DC recipient mice, but enriched for CD8+ T cells and myeloid cells with suppressor‐associated phenotype. Conclusions Autologous IL‐10‐differentiated DC with tolerogenic properties prolong rat‐to‐mouse islets xenograft survival, potentially by locally inducing immune regulatory cells, indicating their potential for regulatory immune cell therapy in xenotransplantation.
Porcine hepatocytes transplanted during acute liver failure might support metabolic functions until the diseased liver recovers its function. Here, we isolated high numbers of viable pig hepatocytes and evaluated hepatocyte functionality after encapsulation. We further investigated whether coculture and coencapsulation of hepatocytes with human multipotent mesenchymal stromal cells (MSC) are beneficial on hepatocyte function. Livers from 10 kg pigs (n = 9) were harvested, and hepatocytes were isolated from liver suspensions for microencapsulation using alginate and poly(ethylene-glycol)- (PEG-) grafted alginate hydrogels, either alone or in combination with MSC. Viability, albumin secretion, and diazepam catabolism of hepatocytes were measured for one week. 9.2 ± 3.6 × 109 hepatocytes with 95.2 ± 3.1% viability were obtained after isolation. At day 3, free hepatocytes displayed 99% viability, whereas microencapsulation in alginate and PEG-grafted alginate decreased viability to 62% and 48%, respectively. Albumin secretion and diazepam catabolism occurred in free and microencapsulated hepatocytes. Coencapsulation of hepatocytes with MSC significantly improved viability and albumin secretion at days 4 and 8 (p < 0.05). Coculture with MSC significantly increased and prolonged albumin secretion. In conclusion, we established a protocol for isolation and microencapsulation of high numbers of viable pig hepatocytes and demonstrated that the presence of MSC is beneficial for the viability and function of porcine hepatocytes.
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