The Israeli team working on this regenerative medicine project has already (in 2022) been successful with mice. Diana Bletter’s August 21, 2025 Times of Israel article, excerpts of which can be found later in this posting, added some details that I appreciated. That said, the press release is quite accessible and informative.
What if we could restore the ability to walk to people paralyzed by injury or illness? This vision is now moving closer to reality. Three years ago, Tel Aviv University researchers succeeded in engineering a human spinal cord in the lab for the first time. Since then, progress has been rapid, with animal trials showing unprecedented success. Now, for the first time, the technology is set to be tested in human patients.
Prof. Tal Dvir, of TAU’s Sagol Center for Regenerative Biotechnology, head of the Nanotechnology Center, and Chief Scientist of the biotech company Matricelf, explains: “The spinal cord is made up of nerve cells that transmit electrical signals from the brain to every part of the body. When the spinal cord is torn due to trauma — from a car accident, a fall, or a battlefield injury — this chain is broken. Think of it like an electrical cable that’s been cut: if the two parts don’t touch, the electrical signal can’t pass. The cable won’t carry electricity, and in the same way, the person can’t transmit the signal beyond the site of the injury.”
This is one of the few injuries in the human body with no natural ability to regenerate. “Neurons are cells that do not divide and do not renew themselves. They are not like skin cells, which can repair themselves after injury. They are more similar to heart cells: once damage occurs, the body cannot restore them,” notes Prof. Dvir.
Engineering a Personalized Implant
To overcome this challenge, the TAU researchers developed a fully personalized process. Blood cells are taken from the patient and reprogrammed through genetic engineering to behave like embryonic stem cells, capable of becoming any type of cell in the body.
Meanwhile, fat tissue from the same patient is used to extract substances such as collagen and sugars. These are used to produce a unique hydrogel. “The beauty of this gel is that it’s also personalized, just like the cells. We take the cells that we’ve reprogrammed into embryonic-like stem cells, place them inside the gel, and mimic the embryonic development of the spinal cord,” says Prof. Dvir.
The result is a complete three-dimensional implant. “At the end of the process, we don’t just turn the cells into motor neurons — because cells alone won’t help us — but into three-dimensional tissue: neuronal networks of the spinal cord. After about a month, we obtain a 3D implant with many neurons that transmit electrical signals. These 3D tissues are then implanted into the damaged area.”
Visualization of the next stage of the research – human spinal cord implants for treating paralysis (Photo: Sagol Center for Regenerative Biotechnology)
From Animals to Human Patients
The researchers first tested the implant in lab animals. “We showed that we can treat animals with chronic injuries. Not animals that were injured just recently, but those we allowed enough time to pass — like a person more than a year after an injury. More than 80% of the animals regained full walking ability,” Prof. Dvir explains.
Encouraged by these results, the team submitted the findings to Israel’s Ministry of Health. “About six months ago we received preliminary approval to begin compassionate-use trials with eight patients. We decided, of course, that the first patient would be Israeli. This is undoubtedly a matter of national pride. The technology was developed here in Israel, at Tel Aviv University and at Matricelf, and from the very beginning it was clear to us that the first-ever surgery would be performed in Israel, with an Israeli patient.” he says.
Looking Ahead
The first implant in a human patient is expected within about a year. For the initial trials, the team will focus on patients whose paralysis is relatively recent — within about a year of injury. “Once we prove that the treatment works — everything is open, and we’ll be able to treat any injury,” says Prof. Dvir.
Behind the initiative are key figures from both academia and industry. Prof. Dvir founded Matricelf in 2019 together with Dr. Alon Sinai, based on the revolutionary organ engineering technology developed at TAU under a licensing agreement through Ramot, the University’s technology transfer company. The company’s CEO is Gil Hakim, while the scientific development is led by Dr. Tamar Harel-Adar and her team.
“They managed to get us to the stage of regulatory approvals so quickly — and that’s amazing,” says Prof. Dvir.
Gil Hakim, CEO of Matricelf , concludes: “This milestone marks the shift from pioneering research to patient treatment. For the first time, we are translating years of successful preclinical work into a procedure for people living with paralysis. Our approach, using each patient’s own cells to engineer a new spinal cord, eliminates key safety risks and positions Matricelf at the forefront of regenerative medicine. If successful, this therapy has the potential to define a new standard of care in spinal cord repair, addressing a multi-billion-dollar market with no effective solutions today. This first procedure is more than a scientific breakthrough, it is a value-inflection point for Matricelf and a step toward transforming an area of medicine long considered untreatable. We are proud that Israel is leading this global effort and are fully committed to bringing this innovation to patients worldwide.”
Diana Bletter’s August 21, 2025 article for The Times of Israel (h/t August 21, 2025 Google alert) covers much of the same ground as the press release but there are some new details, Note: Links have been removed,
…
Prof. Tal Dvir, head of the Sagol Center for Regenerative Biotechnology and the Nanotechnology Center at Tel Aviv University, said his research team is now able to engineer a spinal cord that functions exactly like a natural one by implanting 3D-engineered tissue into the damaged area.
Fusion then occurs between the new tissue and the healthy areas above and below the injury that will end the paralysis.
…
The upcoming spinal cord implant surgery marks the next stage in a process that began about three years ago, when Dvir’s lab at Tel Aviv University succeeded in engineering a personalized 3D spinal cord in the laboratory.
The groundbreaking findings, published in the prestigious journal Advanced Science, demonstrated for the first time ever that mice suffering from chronic paralysis that were treated with these engineered implants started to walk — and even scamper — again.
The success rate with the engineered spinal cord was 80 percent for mice with chronic paralysis. Among those with recent or short-term paralysis, 100% of the mice walked.
…
Patients remain paralyzed because neurons do not renew
Around the world, there are over 15 million people who have suffered spinal cord injuries. Professionals can help stabilize the injury but not much else.
Dvir said that as a result, the damage only worsens. Over time, the damaged area becomes scar tissue.
“The patient remains paralyzed below the site of injury,” he said. “If the injury is in the neck, all four limbs may be paralyzed. If in the lower back, the legs will not move, and so on.”
Spinal cord injuries are one of the very few injuries in the human body that are not impacted by natural regenerative ability, Dvir explained.
“The neurons do not divide and do not renew themselves,” he said. “These cells are not like skin cells, which can heal after injury, but are more like heart cells: Once damaged, the body cannot repair them.”
“The spinal cord is composed of nerve cells that transmit electrical signals from the brain to all parts of the body,” Dvir said. “The decision is made in the brain, the electrical signal passes through the spinal cord, and from there, neurons activate the muscles throughout the body.”
When the spinal cord is severed due to trauma, such as a car accident, a fall, or a combat injury, this chain is broken.
“Think of an electrical cable that has been cut,” Dvir said. “When the two ends no longer touch, the electrical signal cannot pass. The cable will not transmit electricity, and the person cannot transmit the signal beyond the injury.”
Dvir’s team aims to fix that.
Implanting an engineered human spinal cord
Dvir said that the researchers start the process with a small biopsy from the belly.
They then take these blood cells and perform a process known as reprogramming — genetic engineering that transforms the cells into embryonic stem cell-like cells, capable of developing into any cell type in the body.
In the next step, the scientists take fatty tissue from the patient, extract key components such as collagens and sugars, and build a customized hydrogel. The embryonic stem cell-like cells are placed in this gel, and the embryonic development of a spinal cord is mimicked.
This spinal cord will then be transplanted into the human body, restoring the body’s abilities.
…
I have a link to Dvir’s company, Matricelf and a link to and a citation to the Dvir team’s 2022 study,
One more note, there is other work devoted to enable paralyzed people to walk again such as the Walk Again Project (Wikipedia entry), Note: Links have been removed,
Walk Again Project is an international, non-profit consortium led by Miguel Nicolelis, created in 2009 in a partnership between Duke University and the IINN/ELS [International Institute for Neurosciences of Natal – Edmond and Lily Safra or Instituto Internacional de Neurociências Edmond e Lily Safra; (INN-ELS)], where researchers come together to find neuro-rehabilitation treatments for spinal cord injuries,[1][2][3] which pioneered the development and use of the brain–machine interface, including its non-invasive version,[4] with an EEG.[5]
A March 20, 2025 news item on ScienceDaily makes an announcement regarding cyberthreats and medical devices,
A brain implant designed to help control seizures is hijacked. A pacemaker receives fake signals, disrupting its rhythm. A hacker infiltrates an insulin pump, delivering a fatal overdose. While these scenarios sound like scenes from a sci-fi thriller, such cyberhealth threats are of real concern as medical technology moves toward smart, wirelessly connected implants.
Smart bioelectronic implants promise to revolutionize healthcare, giving doctors remote access to monitor and adjust treatments. But as these devices become more advanced, they also become more vulnerable. Just like smartphones and bank accounts, medical implants could be targeted by cybercriminals. And when that happens, the consequences could be life-threatening.
At Rice University, electrical and computer engineer Kaiyuan Yang is working to stay ahead of these threats, developing hacker-resistant implants that protect patients from the dark side of medical innovation.
“As biomedical technology advances, the stakes of security are becoming ever more critical,” said Rice University engineer Kaiyuan Yang, who runs the Secure and Intelligent Micro-Systems (SIMS) Lab. “Imagine a tiny, battery-free medical implant ⎯ no bigger than a grain of rice ⎯ capable of treating diseases without major surgery or medication regimens.
“Such implants, powered wirelessly and connected to the internet through a wearable hub, could make a huge difference for the autonomy and life quality of people living with chronic conditions like epilepsy or treatment-resistant depression, for instance,” said Yang, an associate professor of electrical and computer engineering at Rice.
Advanced wireless implantable technology could enable doctors to monitor patients’ health and adjust treatment remotely, making the need for on-site testing and treatment obsolete. But Yang warns that with this potential comes a serious risk: Hackers could intercept communications, steal passwords or send fake commands, threatening patient safety.
In recent work presented at the International Solid-State Circuits Conference (ISSCC) ⎯ the flagship conference of the Institute of Electrical and Electronics Engineers (IEEE) ⎯ Yang and his team unveiled a first-of-its-kind authentication protocol for wireless, battery-free, ultraminiaturized implants that ensures these devices remain protected while still allowing emergency access. Known as magnetoelectric datagram transport layer security, or ME-DTLS, the protocol exploits a quirk of wireless power transfer, a technology that allows medical implants to be powered externally without a battery. Normally when the external power source ⎯ or in this case the external hub worn by the patient ⎯ moves slightly out of alignment, the amount of power the implant receives fluctuates.
“Lateral or side-to-side movement causes a signal misalignment that is usually considered a flaw in these systems, but we turned it into a security feature by transmitting binary values to specific movements with full awareness of the patient,” Yang said.
For example, by coding short movements as a “1” and longer movements as a “0,” the protocol enables users to input a secure access pattern just by moving the external hub in a specific way. This pattern-based input acts like a second authentication factor, much like entering a PIN after using a password or drawing a pattern to unlock a phone. The overall user experience with the ME-DTLS two-factor authentication closely resembles the process of logging into bank accounts today. Users enter their login credentials, wait for an SMS with a temporary passcode then input this passcode to log in.
This innovation solves two major problems in medical cybersecurity. First, it protects against stolen passwords by requiring a physical confirmation step that cannot be faked remotely. Second, it ensures emergency responders can access the device without needing preshared credentials. Thus, if a patient is unconscious or unable to provide a password, the implant transmits a temporary authentication signal that can only be detected at close range.
“This ensures that only a nearby authorized device can access the implant,” Yang said. “In emergencies, the implant verifies the responder or doctor by the pattern they draw and gives them access even if there is no internet connection.”
By leveraging an intrinsic feature of wireless power transfer systems, the solution developed by Yang and his team avoids the drawbacks of other security measures for implantable technologies, like the addition of bulky sensors.
The researchers tested the pattern input method with volunteers and found that it correctly recognized the patterns 98.72% of the time, proving their solution is both reliable and easy to use. The team also developed a rapid, low-power method for the implant to send data back out securely and effectively.
“To the best of our knowledge, we are the first to utilize the natural flaw of wireless power transfer to send secure information to the implant and enable secure two-factor authentication in miniaturized implants,” Yang said. “Compared to other medical devices, our design offers the best balance between security, efficiency and reliability.”
For patients, this could mean a future where their medical implants are both secure and accessible when it matters most, offering a simple, intuitive way to ensure that only the right people ⎯ whether a doctor, caregiver or emergency responder ⎯ can control the technology inside their bodies.
Yang and his team presented their work at the ISSCC held Feb.16-20 in San Francisco. At the conference, Yang was awarded the IEEE Solid-State Circuits Society New Frontier Award, which recognizes early career researchers “exploring innovative and visionary technical work,” according to the IEEE website. This year, Yang’s team was part of a larger contingent of Rice faculty and students who presented at the conference and were recognized for their achievements.
The work was supported by the National Science Foundation (2146476).
