Existing methods for evaluating the potential gonadotoxicity of environmental agents and pharmaceutical compounds rely heavily on animal studies. The current gold standard in vivo functional assays in animals are limited in their human predictive capacity. In addition, existing human two-dimensional in vitro models of testicular toxicity do not accurately reflect the in vivo situation. A more reliable testicular in vitro model system is needed to better assess the gonadotoxic potential of drugs prior to progression into clinical trials. The overall goal of this study was to develop a three-dimensional (3D) in vitro human testis organoid culture system for use as both a predictive first tier drug-screening tool and as a model of human testicular function. Multicellular human testicular organoids composed of Spermatogonial Stem Cells, Sertoli, Leydig and peritubular cells were created and evaluated over time for morphology, viability, androgen production and ability to support germ cell differentiation. Enzyme-linked immunosorbent assay measurements confirmed that the organoids produced testosterone continuously with and without hCG stimulation. Upregulation of postmeiotic genes including PRM1 and Acrosin, detected by quantitative-PCR, digital PCR and Immunofluorescence, indicated the transition of a small percentage of diploid to haploid germ cells. As a novel screening tool for reproductive toxicity, 3D organoids were exposed to four chemotherapeutic drugs, and they responded in a dose-dependent manner and maintained IC50 values significantly higher than 2D cultures. This 3D human testis organoid system has the potential to be used as a novel testicular toxicity-screening tool and in vitro model for human spermatogenesis.
Type-1 Diabetes (T1D) is a devastating autoimmune disorder which results in the destruction of beta cells within the pancreas. A promising treatment strategy for T1D is the replacement of the lost beta cell mass through implantation of immune-isolated microencapsulated islets referred to as the bioartificial pancreas. The goal of this approach is to restore blood glucose regulation and prevent the long-term comorbidities of T1D without the need for immunosuppressants. A major requirement in the quest to achieve this goal is to address the oxygen needs of islet cells. Islets are highly metabolically active and require a significant amount of oxygen for normal function. During the process of isolation, microencapsulation, and processing prior to transplantation, the islets’ oxygen supply is disrupted, and a large amount of islet cells are therefore lost due to extended hypoxia, thus creating a major barrier to clinical success with this treatment. In this work, we have investigated the oxygen generating compounds, sodium percarbonate (SPO) and calcium peroxide (CPO) as potential supplemental oxygen sources for islets during isolation and encapsulation before and immediately after transplantation. First, SPO particles were used as an oxygen source for islets during isolation. Secondly, silicone films containing SPO were used to provide supplemental oxygen to islets for up to 4 days in culture. Finally, CPO was used as an oxygen source for encapsulated cells by co-encapsulating CPO particles with islets in permselective alginate microspheres. These studies provide an important proof of concept for the utilization of these oxygen generating materials to prevent beta cell death caused by hypoxia.
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