Abstract
Background: In vitro maturation (IVM) is a technology designed to obtain mature oocytes following culture of immature cumulus–oocyte complexes (COC) in vitro. IVM is characterized by minimal patient stimulation, making it attractive for patients with excessive AFC or those requiring immediate fertility preservation. However, the clinical uptake of IVM has been slow, primarily due to lower embryo yield and live birth rate relative to IVF, therefore improving IVM culture is required. Aim: To assess whether supplementation of IVM culture medium with the novel in-house engineered TGFβ proteins cumulin and super-GDF9 improves subsequent embryo development. Method: Immature mouse COCs were cultured by standard IVM or bi-phasic IVM ± cumulin or super-GDF9. Following IVM, cumulus expansion was scored and COCs were fertilized, and cultured to assess embryo development. Differential staining was performed on day 6 blastocysts following bi-phasic IVM to assess cell allocation. In a separate experiment, hyperspectral imaging of autofluorescence was carried out on oocytes and cumulus cells following standard IVM ± cumulin to assess the molecular composition of these cells. Results: Both cumulin and super-GDF9 in standard IVM significantly increased cumulus expansion (P<0001; n=104-115 COCs) and blastocyst rate (53.9% control, 73.6% cumulin, 70.4% super-GDF9; P=0.006; n=382-406 oocytes). Hyperspectral imaging showed that oocytes (n=115-158) and cumulus cells (n=532-600) exposed to cumulin during IVM had a distinct spectral profile that varied dramatically (P<0.005) from untreated cells, demonstrating that cumulin has a major impact on the molecular composition of these cells, likely contributing to the improved oocyte quality. In bi-phasic IVM, cumulin did not significantly alter embryo yield (n=387-424 oocytes) or blastocyst cell number or allocation (n=84-112 blastocysts). Conclusion: Cumulin did not provide an additional beneficial effect in bi-phasic IVM, however in standard IVM, cumulin and super-GDF9 significantly improve oocyte developmental competence suggesting that their effects in human IVM should be investigated.
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