Scientists are working on eye transplants for vision loss. Who will sign up?
Awash in a fluid finely calibrated to keep it alive, a human eye rests inside a transparent cubic device. This ECaBox, or Eyes in a Care Box, is a one-of-a-kind system built by scientists at Barcelona’s Centre for Genomic Regulation (CRG). Their goal is to preserve human eyes for transplantation and related research.
In recent years, scientists have learned to transplant delicate organs such as the liver, lungs or pancreas, but eyes are another story. Even when preserved at the average transplant temperature of 4 Centigrade, they last for 48 hours max. That's one explanation for why transplanting the whole eye isn’t possible—only the cornea, the dome-shaped, outer layer of the eye, can withstand the procedure. The retina, the layer at the back of the eyeball that turns light into electrical signals, which the brain converts into images, is extremely difficult to transplant because it's packed with nerve tissue and blood vessels.
These challenges also make it tough to research transplantation. “This greatly limits their use for experiments, particularly when it comes to the effectiveness of new drugs and treatments,” said Maria Pia Cosma, a biologist at Barcelona’s Centre for Genomic Regulation (CRG), whose team is working on the ECaBox.
Eye transplants are desperately needed, but they're nowhere in sight. About 12.7 million people worldwide need a corneal transplant, which means that only one in 70 people who require them, get them. The gaps are international. Eye banks in the United Kingdom are around 20 percent below the level needed to supply hospitals, while Indian eye banks, which need at least 250,000 corneas per year, collect only around 45 to 50 thousand donor corneas (and of those 60 to 70 percent are successfully transplanted).
As for retinas, it's impossible currently to put one into the eye of another person. Artificial devices can be implanted to restore the sight of patients suffering from severe retinal diseases, but the number of people around the world with such “bionic eyes” is less than 600, while in America alone 11 million people have some type of retinal disease leading to severe vision loss. Add to this an increasingly aging population, commonly facing various vision impairments, and you have a recipe for heavy burdens on individuals, the economy and society. In the U.S. alone, the total annual economic impact of vision problems was $51.4 billion in 2017.
Even if you try growing tissues in the petri dish route into organoids mimicking the function of the human eye, you will not get the physiological complexity of the structure and metabolism of the real thing, according to Cosma. She is a member of a scientific consortium that includes researchers from major institutions from Spain, the U.K., Portugal, Italy and Israel. The consortium has received about $3.8 million from the European Union to pursue innovative eye research. Her team’s goal is to give hope to at least 2.2 billion people across the world afflicted with a vision impairment and 33 million who go through life with avoidable blindness.
Their method? Resuscitating cadaveric eyes for at least a month.
If we succeed, it will be the first intact human model of the eye capable of exploring and analyzing regenerative processes ex vivo. -- Maria Pia Cosma.
“We proposed to resuscitate eyes, that is to restore the global physiology and function of human explanted tissues,” Cosma said, referring to living tissues extracted from the eye and placed in a medium for culture. Their ECaBox is an ex vivo biological system, in which eyes taken from dead donors are placed in an artificial environment, designed to preserve the eye’s temperature and pH levels, deter blood clots, and remove the metabolic waste and toxins that would otherwise spell their demise.
Scientists work on resuscitating eyes in the lab of Maria Pia Cosma.
Courtesy of Maria Pia Cosma.
“One of the great challenges is the passage of the blood in the capillary branches of the eye, what we call long-term perfusion,” Cosma said. Capillaries are an intricate network of very thin blood vessels that transport blood, nutrients and oxygen to cells in the body’s organs and systems. To maintain the garland-shaped structure of this network, sufficient amounts of oxygen and nutrients must be provided through the eye circulation and microcirculation. “Our ambition is to combine perfusion of the vessels with artificial blood," along with using a synthetic form of vitreous, or the gel-like fluid that lets in light and supports the the eye's round shape, Cosma said.
The scientists use this novel setup with the eye submersed in its medium to keep the organ viable, so they can test retinal function. “If we succeed, we will ensure full functionality of a human organ ex vivo. It will be the first intact human model of the eye capable of exploring and analyzing regenerative processes ex vivo,” Cosma added.
A rapidly developing field of regenerative medicine aims to stimulate the body's natural healing processes and restore or replace damaged tissues and organs. But for people with retinal diseases, regenerative medicine progress has been painfully slow. “Experiments on rodents show progress, but the risks for humans are unacceptable,” Cosma said.
The ECaBox could boost progress with regenerative medicine for people with retinal diseases, which has been painfully slow because human experiments involving their eyes are too risky. “We will test emerging treatments while reducing animal research, and greatly accelerate the discovery and preclinical research phase of new possible treatments for vision loss at significantly reduced costs,” Cosma explained. Much less time and money would be wasted during the drug discovery process. Their work may even make it possible to transplant the entire eyeball for those who need it.
“It is a very exciting project,” said Sanjay Sharma, a professor of ophthalmology and epidemiology at Queen's University, in Kingston, Canada. “The ability to explore and monitor regenerative interventions will increasingly be of importance as we develop therapies that can regenerate ocular tissues, including the retina.”
Seemingly, there's no sacred religious text or a holy book prohibiting the practice of eye donation.
But is the world ready for eye transplants? “People are a bit weird or very emotional about donating their eyes as compared to other organs,” Cosma said. And much can be said about the problem of eye donor shortage. Concerns include disfigurement and healthcare professionals’ fear that the conversation about eye donation will upset the departed person’s relatives because of cultural or religious considerations. As just one example, Sharma noted the paucity of eye donations in his home country, Canada.
Yet, experts like Sharma stress the importance of these donations for both the recipients and their family members. “It allows them some psychological benefit in a very difficult time,” he said. So why are global eye banks suffering? Is it because the eyes are the windows to the soul?
Seemingly, there's no sacred religious text or a holy book prohibiting the practice of eye donation. In fact, most major religions of the world permit and support organ transplantation and donation, and by extension eye donation, because they unequivocally see it as an “act of neighborly love and charity.” In Hinduism, the concept of eye donation aligns with the Hindu principle of daan or selfless giving, where individuals donate their organs or body after death to benefit others and contribute to society. In Islam, eye donation is a form of sadaqah jariyah, a perpetual charity, as it can continue to benefit others even after the donor's death.
Meanwhile, Buddhist masters teach that donating an organ gives another person the chance to live longer and practice dharma, the universal law and order, more meaningfully; they also dismiss misunderstandings of the type “if you donate an eye, you’ll be born without an eye in the next birth.” And Christian teachings emphasize the values of love, compassion, and selflessness, all compatible with organ donation, eye donation notwithstanding; besides, those that will have a house in heaven, will get a whole new body without imperfections and limitations.
The explanation for people’s resistance may lie in what Deepak Sarma, a professor of Indian religions and philosophy at Case Western Reserve University in Cleveland, calls “street interpretation” of religious or spiritual dogmas. Consider the mechanism of karma, which is about the causal relation between previous and current actions. “Maybe some Hindus believe there is karma in the eyes and, if the eye gets transplanted into another person, they will have to have that karmic card from now on,” Sarma said. “Even if there is peculiar karma due to an untimely death–which might be interpreted by some as bad karma–then you have the karma of the recipient, which is tremendously good karma, because they have access to these body parts, a tremendous gift,” Sarma said. The overall accumulation is that of good karma: “It’s a beautiful kind of balance,” Sarma said.
For the Jews, Christians, and Muslims who believe in the physical resurrection of the body that will be made new in an afterlife, the already existing body is sacred since it will be the basis of a new refashioned body in an afterlife.---Omar Sultan Haque.
With that said, Sarma believes it is a fallacy to personify or anthropomorphize the eye, which doesn’t have a soul, and stresses that the karma attaches itself to the soul and not the body parts. But for scholars like Omar Sultan Haque—a psychiatrist and social scientist at Harvard Medical School, investigating questions across global health, anthropology, social psychology, and bioethics—the hierarchy of sacredness of body parts is entrenched in human psychology. You cannot equate the pinky toe with the face, he explained.
“The eyes are the window to the soul,” Haque said. “People have a hierarchy of body parts that are considered more sacred or essential to the self or soul, such as the eyes, face, and brain.” In his view, the techno-utopian transhumanist communities (especially those in Silicon Valley) have reduced the totality of a person to a mere material object, a “wet robot” that knows no sacredness or hierarchy of human body parts. “But for the Jews, Christians, and Muslims who believe in the physical resurrection of the body that will be made new in an afterlife, the [already existing] body is sacred since it will be the basis of a new refashioned body in an afterlife,” Haque said. “You cannot treat the body like any old material artifact, or old chair or ragged cloth, just because materialistic, secular ideologies want so,” he continued.
For Cosma and her peers, however, the very definition of what is alive or not is a bit semantic. “As soon as we die, the electrophysiological activity in the eye stops,” she said. “The goal of the project is to restore this activity as soon as possible before the highly complex tissue of the eye starts degrading.” Cosma’s group doesn’t yet know when they will be able to keep the eyes alive and well in the ECaBox, but the consensus is that the sooner the better. Hopefully, the taboos and fears around the eye donations will dissipate around the same time.
Carl Zimmer: Genetically Editing Humans Should Not Be Our Biggest Worry
Carl Zimmer, the award-winning New York Times science writer, recently published a stellar book about human heredity called "She Has Her Mother's Laugh." Truly a magnum opus, the book delves into the cultural and scientific evolution of genetics, the field's outsize impact on society, and the new ways we might fundamentally alter our species and our planet.
"I was only prepared to write about how someday we would cross this line, and actually, we've already crossed it."
Zimmer spoke last week with editor-in-chief Kira Peikoff about the international race to edit the genes of human embryos, the biggest danger he sees for society (hint: it's not super geniuses created by CRISPR), and some outlandish possibilities for how we might reproduce in the future. This interview has been edited and condensed for clarity.
I was struck by the number of surprises you uncovered while researching human heredity, like how fetal cells can endure for a lifetime in a mother's body and brain. What was one of the biggest surprises for you?
Something that really jumped out for me was for the section on genetically modifying people. It does seem incredibly hypothetical. But then I started looking into mitochondrial replacement therapy, so-called "three parent babies." I was really surprised to discover that almost by accident, a number of genetically modified people were created this way [in the late 90s and early 2000s]. They walk among us, and they're actually fine as far as anyone can tell. I was only prepared to write about how someday we would cross this line, and actually, we've already crossed it.
And now we have the current arms race between the U.S. and China to edit diseases out of human embryos, with China being much more willing and the U.S. more reluctant. Do you think it's more important to get ahead or to proceed as ethically as possible?
I would prefer a middle road. I think that rushing into tinkering with the features of human heredity could be a disastrous mistake for a lot of reasons. On the other hand, if we completely retreat from it out of some vague fear, I think that we won't take advantage of the actual benefits that this technology might have that are totally ethically sound.
I think the United Kingdom is actually showing how you can go the middle route with mitochondrial replacement therapy. The United States has just said nope, you can't do it at all, and you have Congressmen talking about how it's just playing God or Frankenstein. And then there are countries like Mexico or the Ukraine where people are doing mitochondrial replacement therapy because there are no regulations at all. It's a wild west situation, and that's not a good idea either.
But in the UK, they said alright, well let's talk about this, let's have a debate in Parliament, and they did, and then the government came up with a well thought-through policy. They decided that they were going to allow for this, but only in places that applied for a license, and would be monitored, and would keep track of the procedure and the health of these children and actually have real data going forward. I would imagine that they're going to very soon have their first patients.
As you mentioned, one researcher recently traveled to Mexico from New York to carry out the so-called "three-parent baby" procedure in order to escape the FDA's rules. What's your take on scientists having to leave their own jurisdictions to advance their research programs under less scrutiny?
I think it's a problem when people who have a real medical need have to leave their own country to get truly effective treatment for it. On the other hand, we're seeing lots of people going abroad to countries that don't monitor all the claims that clinics are making about their treatments. So you have stem cell clinics in all sorts of places that are making all sorts of ridiculous promises. They're not delivering those results, and in some cases, they're doing harm.
"Advances in stem cell biology and reproductive biology are a much bigger challenge to our conventional ideas about heredity than CRISPR is."
It's a tricky tension for sure. Speaking of gene editing humans, you mention in the book that one of the CRISPR pioneers, Jennifer Doudna, now has recurring nightmares about Hitler. Do you think that her fears about eugenics being revived with gene editing are justified?
The word "eugenics" has a long history and it's meant different things to different people. So we have to do a better job of talking about it in the future if we really want to talk about the risks and the promises of technology like CRISPR. Eugenics in its most toxic form was an ideology that let governments, including the United States, sterilize their own citizens by the tens of thousands. Then Nazi Germany also used eugenics as a justification to exterminate many more people.
Nobody's talking about that with CRISPR. Now, are people concerned that we are going to wipe out lots of human genetic diversity with it? That would be a bad thing, but I'm skeptical that would actually ever happen. You would have to have some sort of science fiction one-world government that required every new child to be born with IVF. It's not something that keeps me up at night. Honestly, I think we have much bigger problems to worry about.
What is the biggest danger relating to genetics that we should be aware of?
Part of what made eugenics such a toxic ideology was that it was used as a justification for indifference. In other words, if there are problems in society, like a large swath of people who are living in poverty, well, there's nothing you can do about it because it must be due to genetics.
If you look at genetics as being the sole place where you can solve humanity's problems, then you're going to say well, there's no point in trying to clean up the environment or trying to improve human welfare.
A major theme in your book is that we should not narrow our focus on genes as the only type of heredity. We also may inherit some epigenetic marks, some of our mother's microbiome and mitochondria, and importantly, our culture and our environment. Why does an expanded view of heredity matter?
We should think about the world that our children are going to inherit, and their children, and their children. They're going to inherit our genes, but they're also going to inherit this planet and we're doing things that are going to have an incredibly long-lasting impact on it. I think global warming is one of the biggest. When you put carbon dioxide into the air, it stays there for a very, very long time. If we stopped emitting carbon dioxide now, the Earth would stay warm for many centuries. We should think about tinkering with the future of genetic heredity, but I think we should also be doing that with our environmental heredity and our cultural heredity.
At the end of the book, you discuss some very bizarre possibilities for inheritance that could be made possible through induced pluripotent stem cell technology and IVF -- like four-parent babies, men producing eggs, and children with 8-celled embryos as their parents. If this is where reproductive medicine is headed, how can ethics keep up?
I'm not sure actually. I think that these advances in stem cell biology and reproductive biology are a much bigger challenge to our conventional ideas about heredity than CRISPR is. With CRISPR, you might be tweaking a gene here and there, but they're still genes in an embryo which then becomes a person, who would then have children -- the process our species has been familiar with for a long time.
"We have to recognize that we need a new language that fits with the science of heredity in the 21st century."
We all assume that there's no way to find a fundamentally different way of passing down genes, but it turns out that it's not really that hard to turn a skin cell from a cheek scraping into an egg or sperm. There are some challenges that still have to be worked out to make this something that could be carried out a lot in labs, but I don't see any huge barriers to it. Ethics doesn't even have the language to discuss the possibilities. Like for example, one person producing both male and female sex cells, which are then fertilized to produce embryos so that you have a child who only has one parent. How do we even talk about that? I don't know. But that's coming up fast.
We haven't developed our language as quickly as the technology itself. So how do we move forward?
We have to recognize that we need a new language that fits with the science of heredity in the 21st century. I think one of the biggest problems we have as a society is that most of our understanding about these issues largely comes from what we learned in grade school and high school in biology class. A high school biology class, even now, gets up to Mendel and then stops. Gregor Mendel is a great place to start, but it's a really bad place to stop talking about heredity.
[Ed. Note: Zimmer's book can be purchased through your retailer of choice here.]
The cover of Zimmer's new book about genetics.
Kira Peikoff was the editor-in-chief of Leaps.org from 2017 to 2021. As a journalist, her work has appeared in The New York Times, Newsweek, Nautilus, Popular Mechanics, The New York Academy of Sciences, and other outlets. She is also the author of four suspense novels that explore controversial issues arising from scientific innovation: Living Proof, No Time to Die, Die Again Tomorrow, and Mother Knows Best. Peikoff holds a B.A. in Journalism from New York University and an M.S. in Bioethics from Columbia University. She lives in New Jersey with her husband and two young sons. Follow her on Twitter @KiraPeikoff.
This “Absolutely Tireless” Researcher Made an Important Breakthrough for Cancer Patients
After months of looking at dead cells under a microscope, Theo Roth finally glimpsed what he had been hoping to see—flickers of green. His method was working.
"If we can go into the cell and add in new code and instructions, now we can give it whatever new functions we want."
When Roth joined the laboratory of Alex Marson at the University of California, San Francisco in June 2016, he set to work trying to figure out a new way to engineer human T cells, a type of white blood cell that's an important part of the immune system. If he succeeded, the resulting approach could make it easier and faster for scientists to develop and test cell and gene therapies, new treatments that involve genetically reprogramming the body's own cells.
For decades, researchers have been using engineered viruses to bestow human cells with new genetic characteristics. These so-called viral vectors "infect" human cells, transferring whatever new genetic material scientists put into them. The idea is that this new DNA could give T cells a boost to better fight diseases like cancer and HIV.
Several successful clinical trials have used virally-modified human T cells, and in fact, the U.S. Food and Drug Administration last year approved two such groundbreaking cancer gene therapies, Kymriah and Yescarta. But the process of genetically manipulating cells with viruses is expensive and time-consuming. In addition, viruses tend to randomly insert DNA with little predictability.
"What Theo wanted to do was to paste in big sequences of DNA at a targeted site without viruses," says Marson, an associate professor of microbiology and immunology. "That would have the benefit of being able to rewrite a specific site in the genome and do it flexibly and quickly without having to make a new virus for every site you want to manipulate."
Scientists have for a while been interested in non-viral engineering methods, but T cells are fragile and notoriously difficult to work with.
Previously, Marson's lab had collaborated with CRISPR pioneer Jennifer Doudna and her team at the University of California, Berkeley to use an electrical pulse together with CRISPR components to knock out certain genes. They also found some success with inserting very small pieces of DNA into a targeted site.
But Roth, a 27-year-old graduate student at UCSF pursuing MD and PhD degrees, was determined to figure out how to paste in much bigger sequences of genetic information. Marson says it was an "ambitious" goal. Scientists had tried before, but found that stuffing large chunks of DNA into T cells would quickly kill them.
"If we can go into the cell and add in new code and instructions, now we can give it whatever new functions we want," Roth says. "If you can add in new DNA sequences at the site that you want, then you have a much greater capacity to generate a cell that's going to be therapeutic or curative for a disease."
"He has already made his mark on the field."
So Roth began experimenting with hundreds of different variables a week, trying to find the right conditions to allow him to engineer T cells without the need for viruses. To know if the technique was working, Roth and his colleagues used a green fluorescent protein that would be expressed in cells that had successfully been modified.
"We went from having a lot of dead cells that didn't have any green to having maybe 1 percent of them being green," Roth says. "At that stage we got really excited."
After nearly a year of testing, he and collaborators found a combination of T cell ratios and DNA quantity mixed with CRISPR and zaps of electricity that seemed to work. These electrical pulses, called electroporation, deliver a jolt to cells that makes their membranes temporarily more permeable, allowing the CRISPR system to slip through. Once inside cells, CRISPR seeks out a specific place in the genome and makes a programmed, precise edit.
Roth and his colleagues used the approach to repair a genetic defect in T cells taken from children with a rare autoimmune disease and also to supercharge T cells so that they'd seek out and selectively kill human cancer cells while leaving healthy cells intact. In mice transplanted with human melanoma tissue, the edited T cells went to straight to the cancerous cells and attacked them. The findings were published in Nature in July.
Marson and Roth think even a relatively small number of modified T cells could be effective at treating some cancers, infections, and autoimmune diseases.
Roth is now working with the Parker Institute for Cancer Immunotherapy in San Francisco to engineer cells to treat a variety of cancers and hopefully commercialize his technique. Fred Ramsdell, vice president at the Parker Institute, says he's impressed by Roth's work. "He has already made his mark on the field."
Right now, there's a huge manufacturing backlog for viruses. If researchers want to start a clinical trial to test a new gene or cell therapy, they often have to wait a year to get the viruses they need.
"I think the biggest immediate impact is that it will lower the cost of a starting an early phase clinical trial."
Ramsdell says what Roth's findings allow researchers to do is engineer T cells quickly and more efficiently, cutting the time it takes to make them from several months to just a few weeks. That will allow researchers to develop and test several potential therapies in the lab at once.
"I think the biggest immediate impact is that it will lower the cost of a starting an early phase clinical trial," Roth says.
This isn't the first time Roth's work has been in the spotlight. As an undergraduate at Stanford University, he made significant contributions to traumatic brain injury research by developing a mouse model for observing the brain's cellular response to a concussion. He started the research, which was also published in Nature, the summer before entering college while he was an intern in Dorian McGavern's lab at the National Institutes of Health.
When Roth entered UCSF as a graduate student, his scientific interests shifted.
"It's definitely a big leap" from concussion research, says McGavern, who still keeps in touch with Roth. But he says he's not surprised about Roth's path. "He's absolutely tireless when it comes to the pursuit of science."
Roth says he's optimistic about the potential for gene and cell therapies to cure patients. "I want to try to figure out what one of the next therapies we should put into patients should be."