Researchers from the University of Florida Department
of Animal Sciences have reported
progress in equine reproduction,
demonstrating that frozen-thawed stallion sperm may be more effective for in
vitro fertilisation (IVF) than fresh or chilled semen. The findings, published
in the journal Reproductive Biology, could have significant implications
for the performance horse industry.
In horse breeding, IVF has historically lagged behind its success in other species such as cattle. One major challenge has been the difficulty of achieving proper sperm function outside the body. In particular, stallion sperm require a process known as capacitation before they can penetrate and fertilise an egg. This involves a series of physical and biochemical changes that are highly sensitive to environmental conditions such as temperature and time.
The need for improved IVF techniques is especially relevant in the performance horse sector. Highly valuable mares are often selected for breeding, but not all are able to safely conceive or carry a pregnancy. Certain conditions, including uterine disease, prior foaling injuries, or lameness, may increase the risk associated with pregnancy. Additionally, some mares may be performing at their optimal level and cannot be withdrawn from competition for breeding purposes.
In such cases, producing an embryo via IVF and transferring it into a surrogate mare offers a safer alternative, protecting both the donor mare and the developing foal.
To better understand how to achieve successful fertilisation, the research team investigated how different types of semen - fresh, chilled, and frozen-thawed - respond under capacitating conditions. They also compared various sperm selection methods, including Percoll gradients, Swim-Up techniques, and microfluidic systems*. These approaches were assessed based on key indicators such as sperm motility, acrosome integrity, and biochemical markers like tyrosine phosphorylation.
The results revealed that temperature played a critical role. Incubating sperm at body temperature (38°C) reduced motility, whereas maintaining sperm at ambient temperature allowed optimal capacitation within approximately four hours. At this time point, sperm also showed the highest level of acrosome integrity, an important factor for successful fertilisation.
The research team found that frozen-thawed sperm performed better than fresh or chilled samples in the IVF setting. Although freezing and thawing can place mild stress on sperm cells, this stress appears to trigger changes that promote capacitation. As a result, frozen sperm were able to function effectively with fewer preparatory steps.
Further experiments confirmed fertilisation success through the observation of pro-nuclear formation and early embryo development. Notably, microfluidic sperm selection produced superior results compared to traditional Swim-Up methods, improving sperm quality and fertilisation potential.
Beyond the biological findings, the use of frozen sperm offers practical advantages. Unlike chilled semen, which must be used within a short timeframe, frozen semen can be stored indefinitely and thawed when needed. This flexibility allows veterinarians and breeders to better coordinate the timing of egg collection and fertilisation, making the IVF process more efficient and accessible.
This research represents a significant step forward after more than three decades of limited progress in equine IVF. By identifying conditions that support effective capacitation and demonstrating the advantages of frozen sperm, the study provides a foundation for improving embryo production in horses. For the equine industry, these advances could expand breeding options while prioritising the health and welfare of valuable mares.
For more details, see:
Joao D. de Agostini Losano, Jillian E. Guertin, Maura S. McGraw, Lana Katz, Vilceu Bordignon, Justin W. Callaham, Jose H.F. Pontes, Perla Fleury, Marc Maserati, Carly Turner, Bradford W. Daigneault,
Temporal characterization of conditions that promote functional capacitation of stallion sperm,
Reproductive Biology (2026) Vol 26, 2,101201,
https://doi.org/10.1016/j.repbio.2026.101201
*Percoll gradient centrifugation is a method that separates sperm based on their density. A liquid medium is layered in tubes at different concentrations, and the semen sample is placed on top. When the tube is spun in a centrifuge, sperm cells move through the layers depending on their density and quality. The most viable sperm - those that are motile and structurally normal - tend to settle into a specific layer, while debris, dead sperm, and less functional cells remain elsewhere. This method is widely used because it produces a relatively clean and concentrated sample of high-quality sperm.
Swim-Up technique relies on sperm motility rather than density. In this approach, a semen sample is placed at the bottom of a tube with a layer of culture medium above it. Over time, the most motile sperm actively swim upward into the medium. These sperm are then collected from the top layer. This technique mimics a natural selection process, as only the strongest swimmers are chosen. However, it can result in lower sperm numbers and may not always select for the best overall sperm quality, especially if motility is reduced.
Microfluidic sperm selection systems represent a more modern and precise approach. These systems, such as microfluidic sperm selection, use tiny channels that mimic aspects of the female reproductive tract. Sperm are introduced into a device where they must navigate through narrow pathways and fluid flows. Only sperm with good motility, proper morphology, and functional membranes can successfully pass through the system. This method reduces mechanical stress on the sperm compared to centrifugation and may better preserve their physiological state.
