Thermotaxis has been demonstrated to be an important criterion for sperm evaluation, yet clinical assessment of thermotaxis capacity is currently lacking. In this article, the on-chip thermotaxis evaluation of human sperm is presented for the first time using an interfacial valve-facilitated microfluidic device. The temperature gradient was established and accurately controlled by an external temperature gradient control system. The temperature gradient responsive sperm population was enriched into one of the branch channels with higher temperature setting and the non-responsive ones were evenly distributed into the two branch channels. We employed air-liquid interfacial valves to ensure stable isolation of the two branches, facilitating convenient manipulation of the entrapped sperm. With this device, thermotactic responses were observed in 5.7%-10.6% of the motile sperm moving through four temperature ranges (34.0-35.3 °C, 35.0-36.3 °C, 36.0-37.3 °C, and 37.0-38.3 °C, respectively). In conclusion, we have developed a new method for high throughput clinical evaluation of sperm thermotaxis and this method may allow other researchers to derive better IVF procedure.
A sensitive and high resolution small animal in vivo imaging system using upconversion nanoparticles (UNPs) and microarrays was developed. The fluorescence tomography using UNPs could achieve higher precision than that using ordinary fluorophores, which was theoretically explained by the finite element method (FEM). Given the autofluorescence-insensitive property of UNPs, a high subcutaneous detection sensitivity of 0.93 × 10(-4) wt% could be achieved with a UNP volume of ∼10 μL in tissue phantoms. Furthermore, UNP fluorophore microarrays (25, 50 and 100 μm arrays) embedded under mouse skin were prepared for subcutaneous in vivo detection. An optical clearing method was applied to enhance the skin transparency and improve the spatial resolution. The results demonstrated that the optimized system could achieve a spatial resolution of 50 μm for in vivo detection of subcutaneous UNP microarrays. Taken together, we conclude that the proposed system and UNP microarrays could achieve sensitive, high resolution subcutaneous in vivo detection, and have great potential for high throughput detection of tumors and other diseases.
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