Real time culture and analysis of embryo metabolism using a microfluidic device with deformation based actuation.

We report a computerized microfluidic real time embryo culture and assay device that can perform automated periodic analyses of embryo metabolism. This automated program uses a modified "gated injection" scheme (sample injection, reagent mixing, enzyme reaction of 15 min incubation, and sample detection) to sequentially measure fluorescence from sample, reference, and background (without any analyte) every hour. Measurements assessed with reference solutions demonstrated the stability of these microfluidic measurements over a 24 h period. Furthermore, this system was able to measure time dependent nutrient consumption by single or multiple (10) live mouse blastocyst-stage embryos with pmol h(-1) sensitivity. Mechanical deformation-based microfluidic actuation created by computerized movement of Braille pins enables automated fluid pumping and valving sequences without unwanted gravity-driven backflow or exposure to electrical fields as would be required in electrokinetic schemes. The convenient, non-invasive, and automated nature of these assays open the way for the development of integrated microfluidic platforms for practical single embryo culture and real time biochemical analysis to assess embryo viability and select embryos with the greatest implantation potential, thus improving success in clinical assisted reproductive technology laboratories.

Thiazolidinediones decrease vascular endothelial growth factor (VEGF) production by human luteinized granulosa cells in vitro.

OBJECTIVE: To determine the effect of thiazolidenedione derivatives (TZDs) on vascular endothelial growth factor (VEGF) production by human luteinized granulosa cells and the morphologic development of murine embryos. DESIGN: Prospective, experimental, in vitro and in vivo study. SETTING: Research laboratory. PATIENT(S): Follicular aspirates from 10 women undergoing oocyte retrieval. INTERVENTION(S): Isolated human granulosa cells were treated with a dimethyl sulfoxide (DMSO) control or ciglitazone, in the presence and absence of an hCG stimulus. Embryos extracted from superovulated B6C3F1 female mice were cultured in the presence of DMSO or pioglitazone. MAIN OUTCOME MEASURE(S): Vascular endothelial growth factor concentrations at 24 and 48 hours. Morphologic development of murine embryos at 96 hours. RESULT(S): Following an hCG stimulus, treatment with 20 microM or 40 microM ciglitazone decreased VEGF production in a statistically significant manner at both time intervals. Blastocyst development at 96 hours did not significantly differ between untreated zygotes and those treated with pioglitazone. CONCLUSION(S): Ciglitazone significantly decreased VEGF production by human granulosa cells in an in vitro model. Pioglitazone did not adversely impact the development of cultured murine embryos. Although mechanistic evidence is not provided, the pivotal role of VEGF in ovarian hyperstimulation syndrome prompts investigation of TZDs as a novel treatment for this condition.

Characterization and resolution of evaporation-mediated osmolality shifts that constrain microfluidic cell culture in poly(dimethylsiloxane) devices.

Evaporation is a critical problem when handling submicroliter volumes of fluids. This paper characterizes this problem as it applies to microfluidic cell culture in poly(dimethylsiloxane) (PDMS) devices and provides a practical solution. Evaporation-mediated osmolality shifts through PDMS membranes with varying thicknesses (10, 1, 0.2, or 0.1 mm) were measured over 96 h. Even in humidified cell culture incubators, evaporation through PDMS and associated shifts in the osmolality of culture media was significant and prevented mouse embryo and human endothelial cell growth and development. A simple diffusion model, where the measured diffusion coefficient for PDMS matches reported values of approximately 10-9 m2/s, accounts for these evaporation and osmolality shifts. To overcome this problem, a PDMS-parylene-PDMS hybrid membrane was developed that greatly suppresses evaporation and osmolality shifts, yet possesses thinness and the flexibility necessary to interface with deformation-based microfluidic actuation systems, maintains the clarity for optical microscopy, and enables the successful development of single-cell mouse embryos into blastocysts under static conditions and culture of human endothelial cells under dynamic recirculation of submicroliter volumes of media. These insights and methods demonstrated specifically for embryo and endothelial cell studies will be generally useful for understanding and overcoming evaporation-associated effects in microfluidic cell cultures.