Human Embryos Pull Themselves Into the Uterus With Hidden Forces todayheadline

For the first time, scientists have filmed human embryo implantation in real time, revealing how tiny, developing embryos pull on their surroundings with surprising force to burrow into tissue.

Researchers at the Institute for Bioengineering of Catalonia (IBEC) and Dexeus University Hospital captured the process in 3D using a laboratory-grown model of the uterine lining. Their findings, published in Science Advances, show that these traction forces, combined with mechanosensitivity, are key to how embryos anchor themselves and establish the earliest connection to the mother.

Probing the Mechanics of Life’s First Attachment

Implantation failure is one of the leading causes of infertility, responsible for about 60 percent of miscarriages. Although scientists have studied the biochemical signals involved, the physical forces at work had never been directly observed in humans. Using a gel made of collagen, a fibrous protein abundant in the uterus, the IBEC team recreated the environment a blastocyst encounters just before embedding. This allowed high-resolution, time-lapse imaging and a mechanical analysis known as traction force microscopy.

“We have observed that human embryos burrow into the uterus, exerting considerable force during the process,” said Samuel Ojosnegros, who led the study. “These forces are necessary because the embryos must be able to invade the uterine tissue, becoming completely integrated with it. It is a surprisingly invasive process.”

Human Versus Mouse: Two Strategies for Implantation

To compare species, the team studied both human and mouse embryos on the same platform. Mouse embryos adhered to the surface and spread outward, remodeling collagen in two or three preferred directions. Human embryos behaved differently, embedding themselves more deeply and generating multiple small foci of traction that pulled radially over time. Both species responded to external mechanical cues, but their force patterns reflected their distinct implantation styles.

• Mouse embryos applied anisotropic (directional) forces, with stable displacement axes.
• Human embryos exerted radial pulling forces from several points, integrating deeper into the matrix.
• Low-quality human embryos generated weaker displacements and failed to invade fully.

Cells That Grab and Sense

Microscopy revealed that the cells at the embryo’s outer layer, the trophectoderm, use specialized contact points called focal adhesions and podosome-like structures to grip and pull on the collagen network. In mouse embryos, blocking integrin function or related signaling sharply reduced traction and outgrowth. In both species, certain cells showed active myosin fibers and, in some cases, nuclear localization of YAP, a protein known to respond to mechanical stress.

“We observe that the embryo pulls on the uterine matrix, moving and reorganising it. It also reacts to external force cues,” said co-first author Amélie Godeau. “We hypothesise that contractions occurring in vivo may influence embryo implantation.”

Bridges of Force

In a striking set of experiments, embryos placed near each other or next to cell spheroids formed what the team calls mechanical bridges: aligned collagen fibers under tension connecting the two bodies. Laser-cutting these fibers caused them to snap back, proving that they were actively pulled taut. In mouse pairs, these mechanical interactions sometimes influenced the orientation of the embryo’s developing body axis. Human embryos, too, formed collagen bridges and sent cell projections toward nearby force sources.

Why This Matters for Fertility Research

These insights into the mechanics of implantation could have practical implications for assisted reproduction. Understanding how traction forces and mechanosensitivity relate to successful invasion may help embryologists select the most viable embryos or design culture conditions that mimic the optimal mechanical environment. In natural pregnancies, uterine contractions could provide such cues, subtly steering implantation site and orientation. Future research may uncover whether adjusting mechanical conditions in the lab could improve implantation rates for IVF patients.

Study Details

The experiments were performed with donated surplus embryos from IVF treatments, following Spanish law and ethical guidelines. Human embryos were cultured only up to day 14.

The study involved advanced imaging, matrix stiffness testing, and comparative analysis across species. Collaborators included the Biomimetic Systems for Cell Engineering group at IBEC, the Barcelona Stem Cell Bank, University of Barcelona, Tel Aviv University, the Biomedical Research Networking Centre, and IRB Barcelona.

Journal Reference

Journal: Science Advances
Article Title: Traction force and mechanosensitivity mediate species-specific implantation patterns in human and mouse embryos
DOI: 10.1126/sciadv.adr5199
Publication Date: August 15, 2025