When condensed matter physics meets biology: Does superhydrophobicity benefiting the cryopreservation of human spermatozoa?

With the increasing demand in regenerative and reproductive medicine for successful conservation of living matter, the need of reliable platform in cell banking seems inevitable. Whilst the cells storage at cryogenic temperatures is a well-developed method, far less is known about the efficiency of nanotechnology in cryogenics. The primary objective of this study is to represent the first of its kind experimental results related to cryopreservation of human spermatozoa by means of superhydrophobic carbon soot coatings. The inclusion of soot-based water repellent interface during the freezing and thawing of human semen minimizes the solid-liquid interfacial area, retards the heat transfer rate and promotes the recovery of up to 80% of initial motility of post-thaw sperm cells. Our discoveries reveal a fundamentally new and exciting direction of development of cryopreservation technologies in the battle against painful biopsies and repetitive surgeries.

Superhydrophobic Soot Coated Quartz Crystal Microbalances: A Novel Platform for Human Spermatozoa Quality Assessment.

The functionality of human spermatozoa is a key factor for the success rate of natural human reproduction, but unfortunately the infertility progressively increases due to multifarious environmental factors. Such disquieting statistics requires the employment of sophisticated computer-assisted methods for semen quality analysis, whose precision, however, is unreliable in cases of patients with low sperm concentrations. In this study, we report a novel quartz crystal microbalance (QCM) based biosensor for in-situ quality assessment of male gametes, comprising a superhydrophobic soot coating as an interface sensing material. The soot deposition on the surface of a 5 MHz QCM eliminates the noise that normally arises upon immersion of the uncoated sensor in the test liquid environment, allowing the detection of human spermatozoa down to 1000⁻100,000 units/mL (1⁻100 ppb). Furthermore, the soot coated QCM delimitates in a highly repeatable way the immotile and motile sperm cells by inducing fundamentally distinct responses in respect to sensor sensitivity and signal trends. The obtained results reveal the strong potential of the superhydrophobic QCM for future inclusion in diverse laboratory analyses closely related to the in vitro fertilization procedures, with a final aim of gaining practical approaches for diagnoses and selection of male gametes.