Regenerative medicine has come a long way, baby
After a cloned baby sheep, what started as one of the most controversial areas in medicine is now promising to transform it.
The field of regenerative medicine had a shaky start. In 2002, when news spread about the first cloned animal, Dolly the sheep, a raucous debate ensued. Scary headlines and organized opposition groups put pressure on government leaders, who responded by tightening restrictions on this type of research.
Fast forward to today, and regenerative medicine, which focuses on making unhealthy tissues and organs healthy again, is rewriting the code to healing many disorders, though it’s still young enough to be considered nascent. What started as one of the most controversial areas in medicine is now promising to transform it.
Progress in the lab has addressed previous concerns. Back in the early 2000s, some of the most fervent controversy centered around somatic cell nuclear transfer (SCNT), the process used by scientists to produce Dolly. There was fear that this technique could be used in humans, with possibly adverse effects, considering the many medical problems of the animals who had been cloned.
But today, scientists have discovered better approaches with fewer risks. Pioneers in the field are embracing new possibilities for cellular reprogramming, 3D organ printing, AI collaboration, and even growing organs in space. It could bring a new era of personalized medicine for longer, healthier lives - while potentially sparking new controversies.
Engineering tissues from amniotic fluids
Work in regenerative medicine seeks to reverse damage to organs and tissues by culling, modifying and replacing cells in the human body. Scientists in this field reach deep into the mechanisms of diseases and the breakdowns of cells, the little workhorses that perform all life-giving processes. If cells can’t do their jobs, they take whole organs and systems down with them. Regenerative medicine seeks to harness the power of healthy cells derived from stem cells to do the work that can literally restore patients to a state of health—by giving them healthy, functioning tissues and organs.
Modern-day regenerative medicine takes its origin from the 1998 isolation of human embryonic stem cells, first achieved by John Gearhart at Johns Hopkins University. Gearhart isolated the pluripotent cells that can differentiate into virtually every kind of cell in the human body. There was a raging controversy about the use of these cells in research because at that time they came exclusively from early-stage embryos or fetal tissue.
Back then, the highly controversial SCNT cells were the only way to produce genetically matched stem cells to treat patients. Since then, the picture has changed radically because other sources of highly versatile stem cells have been developed. Today, scientists can derive stem cells from amniotic fluid or reprogram patients’ skin cells back to an immature state, so they can differentiate into whatever types of cells the patient needs.
In the context of medical history, the field of regenerative medicine is progressing at a dizzying speed. But for those living with aggressive or chronic illnesses, it can seem that the wheels of medical progress grind slowly.
The ethical debate has been dialed back and, in the last few decades, the field has produced important innovations, spurring the development of whole new FDA processes and categories, says Anthony Atala, a bioengineer and director of the Wake Forest Institute for Regenerative Medicine. Atala and a large team of researchers have pioneered many of the first applications of 3D printed tissues and organs using cells developed from patients or those obtained from amniotic fluid or placentas.
His lab, considered to be the largest devoted to translational regenerative medicine, is currently working with 40 different engineered human tissues. Sixteen of them have been transplanted into patients. That includes skin, bladders, urethras, muscles, kidneys and vaginal organs, to name just a few.
These achievements are made possible by converging disciplines and technologies, such as cell therapies, bioengineering, gene editing, nanotechnology and 3D printing, to create living tissues and organs for human transplants. Atala is currently overseeing clinical trials to test the safety of tissues and organs engineered in the Wake Forest lab, a significant step toward FDA approval.
In the context of medical history, the field of regenerative medicine is progressing at a dizzying speed. But for those living with aggressive or chronic illnesses, it can seem that the wheels of medical progress grind slowly.
“It’s never fast enough,” Atala says. “We want to get new treatments into the clinic faster, but the reality is that you have to dot all your i’s and cross all your t’s—and rightly so, for the sake of patient safety. People want predictions, but you can never predict how much work it will take to go from conceptualization to utilization.”
As a surgeon, he also treats patients and is able to follow transplant recipients. “At the end of the day, the goal is to get these technologies into patients, and working with the patients is a very rewarding experience,” he says. Will the 3D printed organs ever outrun the shortage of donated organs? “That’s the hope,” Atala says, “but this technology won’t eliminate the need for them in our lifetime.”
New methods are out of this world
Jeanne Loring, another pioneer in the field and director of the Center for Regenerative Medicine at Scripps Research Institute in San Diego, says that investment in regenerative medicine is not only paying off, but is leading to truly personalized medicine, one of the holy grails of modern science.
This is because a patient’s own skin cells can be reprogrammed to become replacements for various malfunctioning cells causing incurable diseases, such as diabetes, heart disease, macular degeneration and Parkinson’s. If the cells are obtained from a source other than the patient, they can be rejected by the immune system. This means that patients need lifelong immunosuppression, which isn’t ideal. “With Covid,” says Loring, “I became acutely aware of the dangers of immunosuppression.” Using the patient’s own cells eliminates that problem.
Microgravity conditions make it easier for the cells to form three-dimensional structures, which could more easily lead to the growing of whole organs. In fact, Loring's own cells have been sent to the ISS for study.
Loring has a special interest in neurons, or brain cells that can be developed by manipulating cells found in the skin. She is looking to eventually treat Parkinson’s disease using them. The manipulated cells produce dopamine, the critical hormone or neurotransmitter lacking in the brains of patients. A company she founded plans to start a Phase I clinical trial using cell therapies for Parkinson’s soon, she says.
This is the culmination of many years of basic research on her part, some of it on her own cells. In 2007, Loring had her own cells reprogrammed, so there’s a cell line that carries her DNA. “They’re just like embryonic stem cells, but personal,” she said.
Loring has another special interest—sending immature cells into space to be studied at the International Space Station. There, microgravity conditions make it easier for the cells to form three-dimensional structures, which could more easily lead to the growing of whole organs. In fact, her own cells have been sent to the ISS for study. “My colleagues and I have completed four missions at the space station,” she says. “The last cells came down last August. They were my own cells reprogrammed into pluripotent cells in 2009. No one else can say that,” she adds.
Future controversies and tipping points
Although the original SCNT debate has calmed down, more controversies may arise, Loring thinks.
One of them could concern growing synthetic embryos. The embryos are ultimately derived from embryonic stem cells, and it’s not clear to what stage these embryos can or will be grown in an artificial uterus—another recent invention. The science, so far done only in animals, is still new and has not been widely publicized but, eventually, “People will notice the production of synthetic embryos and growing them in an artificial uterus,” Loring says. It’s likely to incite many of the same reactions as the use of embryonic stem cells.
Bernard Siegel, the founder and director of the Regenerative Medicine Foundation and executive director of the newly formed Healthspan Action Coalition (HSAC), believes that stem cell science is rapidly approaching tipping point and changing all of medical science. (For disclosure, I do consulting work for HSAC). Siegel says that regenerative medicine has become a new pillar of medicine that has recently been fast-tracked by new technology.
Artificial intelligence is speeding up discoveries and the convergence of key disciplines, as demonstrated in Atala’s lab, which is creating complex new medical products that replace the body’s natural parts. Just as importantly, those parts are genetically matched and pose no risk of rejection.
These new technologies must be regulated, which can be a challenge, Siegel notes. “Cell therapies represent a challenge to the existing regulatory structure, including payment, reimbursement and infrastructure issues that 20 years ago, didn’t exist.” Now the FDA and other agencies are faced with this revolution, and they’re just beginning to adapt.
Siegel cited the 2021 FDA Modernization Act as a major step. The Act allows drug developers to use alternatives to animal testing in investigating the safety and efficacy of new compounds, loosening the agency’s requirement for extensive animal testing before a new drug can move into clinical trials. The Act is a recognition of the profound effect that cultured human cells are having on research. Being able to test drugs using actual human cells promises to be far safer and more accurate in predicting how they will act in the human body, and could accelerate drug development.
Siegel, a longtime veteran and founding father of several health advocacy organizations, believes this work helped bring cell therapies to people sooner rather than later. His new focus, through the HSAC, is to leverage regenerative medicine into extending not just the lifespan but the worldwide human healthspan, the period of life lived with health and vigor. “When you look at the HSAC as a tree,” asks Siegel, “what are the roots of that tree? Stem cell science and the huge ecosystem it has created.” The study of human aging is another root to the tree that has potential to lengthen healthspans.
The revolutionary science underlying the extension of the healthspan needs to be available to the whole world, Siegel says. “We need to take all these roots and come up with a way to improve the life of all mankind,” he says. “Everyone should be able to take advantage of this promising new world.”
Technology is Redefining the Age of 'Older Mothers'
Scientists are working on technologies that would enable more 70-year-old women to have babies.
In October 2021, a woman from Gujarat, India, stunned the world when it was revealed she had her first child through in vitro fertilization (IVF) at age 70. She had actually been preceded by a compatriot of hers who, two years before, gave birth to twins at the age of 73, again with the help of IVF treatment. The oldest known mother to conceive naturally lived in the UK; in 1997, Dawn Brooke conceived a son at age 59.
These women may seem extreme outliers, almost freaks of nature; in the US, for example, the average age of first-time mothers is 26. A few decades from now, though, the sight of 70-year-old first-time mothers may not even raise eyebrows, say futurists.
“We could absolutely have more 70-year-old mothers because we are learning how to regulate the aging process better,” says Andrew Hessel, a microbiologist and geneticist, who cowrote "The Genesis Machine," a book about “rewriting life in the age of synthetic biology,” with Amy Webb, the futurist who recently wondered why 70-year-old women shouldn’t give birth.
Technically, we're already doing this, says Hessel, pointing to a technique known as in vitro gametogenesis (IVG). IVG refers to turning adult cells into sperm or egg cells. “You can think of it as the upgrade to IVF,” Hessel says. These vanguard stem cell research technologies can take even skin cells and turn them into induced pluripotent stem cells (iPSCs), which are basically master cells capable of maturing into any human cell, be it kidney cells, liver cells, brain cells or gametes, aka eggs and sperm, says Henry T. “Hank” Greely, a Stanford law professor who specializes in ethical, legal, and social issues in biosciences.
Mothers over 70 will be a minor blip, statistically speaking, Greely predicts.
In 2016, Greely wrote "The End of Sex," a book in which he described the science of making gametes out of iPSCs in detail. Greely says science will indeed enable us to see 70-year-old new mums fraternize with mothers several decades younger at kindergartens in the (not far) future. And it won’t be that big of a deal.
“An awful lot of children all around the world have been raised by grandmothers for millennia. To have 70-year-olds and 30-year-olds mingling in maternal roles is not new,” he says. That said, he doubts that many women will want to have a baby in the eighth decade of their life, even if science allows it. “Having a baby and raising a child is hard work. Even if 1% of all mothers are over 65, they aren’t going to change the world,” Greely says. Mothers over 70 will be a minor blip, statistically speaking, he predicts. But one thing is certain: the technology is here.
And more technologies for the same purpose could be on the way. In March 2021, researchers from Monash University in Melbourne, Australia, published research in Nature, where they successfully reprogrammed skin cells into a three-dimensional cellular structure that was morphologically and molecularly similar to a human embryo–the iBlastoid. In compliance with Australian law and international guidelines referencing the “primitive streak rule," which bans the use of embryos older than 14 days in scientific research, Monash scientists stopped growing their iBlastoids in vitro on day 11.
“The research was both cutting-edge and controversial, because it essentially created a new human life, not for the purpose of a patient who's wanting to conceive, but for basic research,” says Lindsay Wu, a senior lecturer in the School of Medical Sciences at the University of New South Wales (UNSW), in Kensington, Australia. If you really want to make sure what you are breeding is an embryo, you need to let it develop into a viable baby. “This is the real proof in the pudding,'' says Wu, who runs UNSW’s Laboratory for Ageing Research. Then you get to a stage where you decide for ethical purposes you have to abort it. “Fiddling here a bit too much?” he asks. Wu believes there are other approaches to tackling declining fertility due to older age that are less morally troubling.
He is actually working on them. Why would it be that women, who are at peak physical health in almost every other regard, in their mid- to late- thirties, have problems conceiving, asked Wu and his team in a research paper published in 2020 in Cell Reports. The simple answer is the egg cell. An average girl in puberty has between 300,000 and 400,000 eggs, while at around age 37, the same woman has only 25,000 eggs left. Things only go downhill from there. So, what torments the egg cells?
The UNSW team found that the levels of key molecules called NAD+ precursors, which are essential to the metabolism and genome stability of egg cells, decline with age. The team proceeded to add these vitamin-like substances back into the drinking water of reproductively aged, infertile lab mice, which then had babies.
“It's an important proof of concept,” says Wu. He is investigating how safe it is to replicate the experiment with humans in two ongoing studies. The ultimate goal is to restore the quality of egg cells that are left in patients in their late 30s and early- to mid-40s, says Wu. He sees the goal of getting pregnant for this age group as less ethically troubling, compared to 70-year-olds.
But what is ethical, anyway? “It is a tricky word,” says Hessel. He differentiates between ethics, which represent a personal position and may, thus, be more transient, and morality, longer lasting principles embraced across society such as, “Thou shalt not kill.” Unprecedented advances often bring out fear and antagonism until time passes and they just become…ordinary. When IVF pioneer Landrum Shettles tried to perform IVF in 1973, the chairman of Columbia’s College of Physicians and Surgeons interdicted the procedure at the last moment. Almost all countries in the world have IVF clinics today, and the global IVF services market is clearly a growth industry.
Besides, you don’t have a baby at 70 by accident: you really want it, Greely and Hessel agree. And by that age, mothers may be wiser and more financially secure, Hessel says (though he is quick to add that even the pregnancy of his own wife, who had her child at 40, was a high-risk one).
As a research question, figuring out whether older mothers are better than younger ones and vice-versa entails too many confounding variables, says Greely. And why should we focus on who’s the better mother anyway? “We've had 70-year-old and 80-year-old fathers forever–why should people have that much trouble getting used to mothers doing the same?” Greely wonders. For some women having a child at an old(er) age would be comforting; maybe that’s what matters.
And the technology to enable older women to have children is already here or coming very soon. That, perhaps, matters even more. Researchers have already created mice–and their offspring–entirely from scratch in the lab. “Doing this to produce human eggs is similar," says Hessel. "It is harder to collect tissues, and the inducing cocktails are different, but steady advances are being made." He predicts that the demand for fertility treatments will keep financing research and development in the area. He says that big leaps will be made if ethical concerns don’t block them: it is not far-fetched to believe that the first baby produced from lab-grown eggs will be born within the next decade.
In an op-ed in 2020 with Stat, Greely argued that we’ve already overcome the technical barrier for human cloning, but no one's really talking about it. Likewise, scientists are also working on enabling 70-year-old women to have babies, says Hessel, but most commentators are keeping really quiet about it. At least so far.
New Cell Therapies Give Hope to Diabetes Patients
Researchers are developing new cell therapies that could cure Type 1 diabetes and make constant management of the disease a way of the past.
For nearly four decades, George Huntley has thought constantly about his diabetes. Diagnosed in 1983 with Type 1 (insulin-dependent) diabetes, Huntley began managing his condition with daily finger sticks to check his blood glucose levels and doses of insulin that he injected into his abdomen. Even now, with an insulin pump and a device that continuously monitors his glucose, he must consider how every meal will affect his blood sugar, checking his monitor multiple times each hour.
Like many of those who depend on insulin injections, Huntley is simultaneously grateful for the technology that makes his condition easier to manage and tired of thinking about diabetes. If he could wave a magic wand, he says, he would make his diabetes disappear. So when he read about biotechs like ViaCyte and Vertex Pharmaceuticals developing new cell therapies that have the potential to cure Type 1 diabetes, Huntley was excited.
You also won’t see him signing up any time soon. The therapies under development by both companies would require a lifelong regimen of drugs for suppressing the immune system to prevent the body from rejecting the foreign cells. It’s a problem also seen in the transplant of insulin-producing cells of the pancreas – called islet cells – from deceased donors. To Howard Foyt, chief medical officer at ViaCyte, a San Diego-based biotech specializing in the development of cell therapies for diabetes, the tradeoff is worth it.
“A lot of the symptoms of diabetes are not something that you wear on your arm, so to speak. You’re not necessarily conscious of them until you’re successfully treated, and you feel better,” Foyt says.
For many with diabetes, managing these symptoms is a constant game of Whack-a-Mole. “Any form of treatment that gets someone closer to feeling good is a victory,” he says.
“Am I going to be trading diabetes for cancer? That’s not a chance I
want to take."
But not everyone is convinced. What’s more, it’s likely that the availability of these cell therapies will be limited to those with life-threatening diabetes symptoms, such as hypoglycemia unawareness. To Huntley, these therapies remain a bit of a Faustian bargain.
“Am I going to be trading diabetes for cancer? That’s not a chance I want to take,” he says.
The discovery of insulin in 1921 transformed Type 1 diabetes from a death sentence into a potentially manageable condition. Even as better versions of insulin hit the market—ones that weren’t derived from pigs and wouldn’t provoke an allergic response, longer-acting insulin, insulin pens—they didn’t change the reality that those with Type 1 diabetes remained dependent on insulin. Even the most advanced continuous glucose monitors (which tests blood sugar levels every few minutes, 24/7) and insulin pumps don’t perform as well as a healthy pancreas.
Whether by injection or pump, someone with diabetes needs to administer the insulin their body no longer makes. With advances in organ transplantation, the concept of transplanting insulin-producing pancreatic beta cells seemed obvious. After more than a decade of painstaking work, James Shapiro, who directs the Islet Transplant Program at the University of Albania, honed a process called the Edmonton Protocol for pancreas transplants. For a few patients who couldn’t control their blood sugars any other way, the Edmonton Protocol became a life saver. Some of these patients were even able to stop insulin completely, Shapiro says. But the high cost of organ transplant and a chronic shortage of donor organs, pancreas or otherwise, meant that only a small handful of patients could benefit.
Stem cells, however, can be grown in vats, meaning that supply would never be an issue. “We would be going from a very successful treatment of today to a potential cure tomorrow,” Shapiro says.
In 2014, spurred by his own children’s diagnoses with Type 1 Diabetes, stem cell biologist Doug Melton of Harvard University figured out a way to differentiate embryonic stem cells into functional pancreatic beta cells. It was a long process, explains immunoengineer Alice Tomei at the University of Miami, because “the islet is not one cell, it's like a mini-organ that has its own needs.”
Add on the risk of rejection and autoimmunity, and Tomei says that scientists soon realized that chronic and systemic immunosuppression was the only way forward. Over the next several years, Melton improved his approach to yield more cells with fewer impurities. Melton partnered with Boston-based Vertex Pharmaceuticals to create a cell therapy called VX-880.
The first patient received his dose earlier in 2021. In October, Vertex released 90-day results from the Phase 1/2 trial, which revealed the patient was able to reduce his insulin usage from an average of 34 units per day to just 2.9 units per day. The tradeoff is a lifelong need for immunosuppressive drugs to prevent the body from attacking both foreign cells and pancreatic beta cells. It’s what recipients of ViaCyte’s first-gen PEC-Direct will also need. For Foyt, it’s an easy choice.
“At this point in time, immunosuppression is the necessary evil,” he says. “For parents, would you like to worry about going into your child’s bedroom every morning and not knowing if they’re going to be alive or dead? It’s uncommon, but it does occur.”
Not everyone, however, finds the trade-off easy to swallow. Especially with COVID-19 cases reaching record highs, the prospect of reducing his immune function at a time when he needs it most doesn’t sit well with Huntley. The risks of immunosuppression also mean that diabetes cell therapies are limited to those patients with life-threatening complications.
It’s why ViaCyte has created two new iterations of cellular therapies that would eliminate this need. The ViaCyte-Encap contains the cells in a permeable container that allows oxygen, insulin, and nutrients to flow freely but prevents immune system access. Their latest model, PEC-QT, just began safety trials with Shapiro’s lab at the University of Alberta and uses gene editing to eliminate any cellular markers that would trigger an immune response.
Sanjoy Dutta, vice president of research at JDRF International, a nonprofit that funds the study of diabetes, is thrilled with the progress that’s been made around cell therapies, but he cautions it’s still early days. “We have proven that these cells can be made. What we haven’t seen is are they going to work for six months, two years, five years? It’s a challenge we still need to overcome,” he says.
Iowa social worker Jodi Lynn’s concerns echo Dutta’s. Lynn was diagnosed with diabetes in 1998 at age 14 after a bout of severe influenza, spends each day inventorying supplies, planning her food intake, and maintaining her insulin pump and glucose monitor. These newer technologies dramatically improved her blood sugar control but, like everyone with diabetes, Lynn remains at high risk for complications, such as diabetic ketoacidosis, heart disease, vision loss, and kidney failure. Lynn, already considered immunocompromised due to medications she takes for another autoimmune condition, is less concerned with immune suppression than the untested nature of these therapies.
“I want to know that they will work long-term,” she says.