“Synthetic Embryos”: The Wrong Term For Important New Research
As a subject of research, an unusual degree of consensus appears to exist among scientists, politicians and the public about human embryos being deserving of special considerations. But what those special considerations should be is less clear. And this is where the subject becomes contentious and opinions diverge because, somewhat surprisingly, what really represents a human embryo has so far not been resolved.
"Prior to implantation, embryos must be given a different level of reverence than after implantation."
In 2002, Howard W. Jones Jr., widely considered the "father" of in vitro fertilization (IVF) in the U.S., argued in a widely acclaimed article titled "What is an embryo?" that a precondition for the definition of a human embryo was successful implantation. Only once implantation established a biological unit between embryo and mother, could a relatively small number of human cells be considered a human embryo.
Because he felt strongly that human embryos, indeed, deserve special considerations, and should receive those during IVF, he pointed out that, even inside a woman's body, most human embryos (in contrast to other species) never implant and, therefore, are never given a chance at human life. Consequently, he reasoned that prior to implantation, embryos must be given a different level of reverence than after implantation.
"One cannot help but wonder about the fog of misconceptions and misrepresentations that still surrounds what an embryo is."
This difference, he felt, should also be reflected in scientific language, proposing that embryos prior to implantation in daily IVF practice be called "pre-embryos," with the term "embryo" reserved for post-implantation-stage embryos. Then still unknown to Jones, recent research findings support this viewpoint, since genetic profiles of pre- and post-implantation stage embryos greatly differ.
In an analogy to nature, which in humans allows implantation of only a small minority of naturally generated pre-embryos, IVF centers around the world routinely discard large numbers of pre-embryos, judged inadequate for producing normal pregnancies. Jones' suggestion that only post-implantation embryos should be considered embryos deserving of special considerations, therefore, not only appears prescient and considerate of current IVF practices, but grounded in scientific reality. One, therefore, cannot help but wonder about the fog of misconceptions and misrepresentations that still surrounds what an embryo is.
"Much of the regulatory environment surrounding research on human embryos is guided by emotions rather than science and logical thinking."
In 1984, a British ethics committee issued the Warnock Report, which still today prohibits scientists worldwide from studying human embryos in a lab beyond 14 days from fertilization or past formation of the so-called primitive streak, whichever comes first. Well-meaning in its day, its intent was to apply special considerations to human pre-embryos by protecting them from the potential of "feeling pain," once the primitive streak arose on day-15 of development. Formation of the primitive streak signifies a process known as gastrulation, when a subset of cells from the inner cell mass of the pre-embryo are transformed into the three germ layers that comprise all tissues of the developing embryo: The ectoderm, which gives rise to the nervous system; the mesoderm, which gives rise to the circulatory system, muscle, and kidneys; and the endoderm which gives rise to the interior lining of the digestive and respiratory tracts, among other tissues.
That pre-embryos may feel pain at that stage of development was far-fetched in 1984; in view of what we have learned about early human embryology in the 33 years since, it remains untenable today. And, yet, scientists all over the world remain bound by the ethical constraints imposed by the Warnock Report.
A similar ethical paradox exists today for guidelines affecting huge numbers of so-called "abandoned" cryopreserved embryos, often stored ad infinitum in IVF centers all over the world. These are pre-embryos, whose "parents" are no longer responsive to queries from their IVF centers. Current U.S. guidelines allow the disposal of such pre-embryos but prohibit their use in research that may benefit mankind. One, however, wonders whether disposal of huge numbers of abandoned embryos is really more ethical than their use in potentially life-saving human research?
That much of the regulatory environment surrounding research on human embryos is, indeed, guided by emotions rather than science and logical thinking, is also demonstrated by recently expressed concern about so-called "artificial" or "synthetic" embryos. Though both of these terms suggest impending ability to create human embryos from synthetic building blocks, this is not what these terms are meant to describe (such abilities also are not on the horizon). They also do not describe abilities to create gametes (i.e., eggs and sperm) from somatic cells by reprogramming adult peripheral cells, which has already been successfully done in mice by Japanese investigators, leading to the creation of healthy embryos and births and three generations of healthy pubs. Such an approach is at least conceivable as an upcoming infertility treatment.
"A team of biologists and engineers at the University of Michigan recently received media attention after creating organoids from embryonic stem cells that resembled human embryos."
What all of this noise is really about is the discovery that, as several Rockefeller University investigators recently noted, "Cells have an intrinsic ability to self-assemble and self-organize into complex and functional tissues and organs." Investigators have taken advantage of this ability by creating in the lab so-called "organoids" from accumulations of individual embryonic stem cells. They are defined by three characteristics: (i) they contain a variety of cell types and tissue layers, all typical for a given organ; (ii) these cells are organized similarly to their organization in a specific organ; and (iii) the organoid mimics functions of the organ.
Several other biologists from the Cincinnati Children Hospital Medical Center recently noted that in the last five years, quite a variety of human stem cell-derived organoids, including all three germ layers, have been generated by different research groups around the world, thereby establishing new human model systems that can be used outside the body, in a dish, to investigate otherwise difficult-to-approach organs. Interestingly, they can also be used to investigate early stages of human embryological development.
A team of biologists and engineers at the University of Michigan recently received media attention after creating organoids from embryonic stem cells that resembled human embryos and, therefore, were given the name "embroids." Though clearly not embryos (the only thing they had in common with human embryos were cell types), they were nevertheless awarded in at least one article the identity of "artificial embryos," which "no one knows how to handle." As Howard Jones so correctly noted, with the word embryo often comes undeserved reverence.
"Any association with the term "embryo" should be avoided; it is not only misleading and irresponsible but scientifically incorrect."
Artificial embryos, therefore, do not exist. Organoids that resemble embryos (i.e., "embroids"), while potentially very useful research objects in studies of early human embryonic cell organization and lineage development, are not embryos--not even pre-embryos. Special considerations for "artificial" or "synthetic" embryos, as recently advocated by some scientists, therefore, appear ethically undeserved. How misdirected and forced some of these efforts are is probably best demonstrated by a recent publication in which a group of Harvard University investigators proposed the term "synthetic human entities with embryo-like features" or SHEEFS" in place of "organoids." Preferably, however, in describing these laboratory-created entities, any association with the term "embryo" should be avoided. It is not only misleading and irresponsible but scientifically incorrect.
Clinical reproductive medicine and reproductive biology, for valid ethical reasons, but also because of myths, misperceptions and, sometimes, outright misrepresentations of facts for political reasons, are under more public scrutiny than most other science areas. Yet, at least in the realm of biomedical research, nothing appears more important than better understanding the first few days of human embryo development. A recent study involving genetic editing of human embryos, reported by British investigators in Nature, once again confirmed what biologist have known for some time: No animal model faithfully recapitulates most of human developmental origins. The most important secrets nature still has to tell us, will not be revealed through mouse or other animal studies. We will discover them only through the study of early-stage human embryos – and we, therefore, should not limit the use of lab-grown organoids to help further that research.
Understanding early human development "will not only greatly enhance the biological understanding of our species; but also will open groundbreaking new therapeutic options in all areas of medicine."
As Howard Jones intuitively noticed, words matter. Appropriate and uniformly accepted definitions and terms are not only essential for scientific communications but, within the context of human reproduction, often elicit strong emotional reactions, and are easily misappropriated by those opposed to most interventions into human reproduction.
Who does not recall the early days of IVF in the late 1970s, when even reputable news outlets raised the specter of Frankenstein monsters created through the IVF process? Millions of IVF births later, a Nobel Prize in Medicine and Physiology was in 2010 finally awarded to the biologist Robert Edwards who, together with the gynecologist Patrick Steptoe, reported the first live birth through IVF on July 25, 1978. Many more awards are still waiting for recipients who through the study of early human embryo development will discover how cell fate is determined and cells acquire highly specific functions; how rapid cell proliferation takes place and, when required, stops; why chromosomal abnormalities are so common in early stage embryos and what their function may be.
Those who will discover these and many other important answers, will not only greatly enhance the biological understanding of our species; but also will open groundbreaking new therapeutic options in all areas of medicine. Learning how to control cell proliferation, for example, will likely revolutionize cancer therapy; I started my research career in biology with a study published in 1980 of "common denominators of pregnancy and malignancy." If regulatory prohibitions are not allowed to interfere in rapidly progressing research opportunities involving organoids and pre-embryos, we will, finally, see the circle closing, with the most rewarding benefits for mankind ever achieved through biological research.
Editor's Note: Read a different viewpoint here written by one of the world's top experts on the ethics of stem cell research.
How to Measure Your Stress, with Dr. Rosalind Picard
Today’s podcast guest is Rosalind Picard, a researcher, inventor named on over 100 patents, entrepreneur, author, professor and engineer. When it comes to the science related to endowing computer software with emotional intelligence, she wrote the book. It’s published by MIT Press and called Affective Computing.
Dr. Picard is founder and director of the MIT Media Lab’s Affective Computing Research Group. Her research and engineering contributions have been recognized internationally. For example, she received the 2022 International Lombardy Prize for Computer Science Research, considered by many to be the Nobel prize in computer science.
Through her research and companies, Dr. Picard has developed wearable sensors, algorithms and systems for sensing, recognizing and responding to information about human emotion. Her products are focused on using fitness trackers to advance clinical quality treatments for a range of conditions.
Meanwhile, in just the past few years, numerous fitness tracking companies have released products with their own stress sensors and systems. You may have heard about Fitbit’s Stress Management Score, or Whoop’s Stress Monitor – these features and apps measure things like your heart rhythm and a certain type of invisible sweat to identify stress. They’re designed to raise awareness about forms of stress such as anxieties and anger, and suggest strategies like meditation to relax in real time when stress occurs.
But how well do these off-the-shelf gadgets work? There’s no one more knowledgeable and experienced than Rosalind Picard to explain the science behind these stress features, what they do exactly, how they might be able to help us, and their current shortcomings.
Dr. Picard is a member of the National Academy of Engineering and a Fellow of the National Academy of Inventors, and a popular speaker who’s given over a hundred invited keynote talks and a TED talk with over 2 million views. She holds a Bachelors in Electrical Engineering from Georgia Tech, and Masters and Doctorate degrees in Electrical Engineering and Computer Science from MIT. She lives in Newton, Massachusetts with her husband, where they’ve raised three sons.
In our conversation, we discuss stress scores on fitness trackers to improve well-being. She describes the difference between commercial products that might help people become more mindful of their health and products that are FDA approved and really capable of advancing the science. We also talk about several fascinating findings and concepts discovered in Dr. Picard’s lab including the multiple arousal theory, a phenomenon you’ll want to hear about. And we explore the complexity of stress, one reason it’s so tough to measure. For example, many forms of stress are actually good for us. Can fitness trackers tell the difference between stress that’s healthy and unhealthy?
Show links:
- Dr. Picard’s book, Affective Computing
- Dr. Picard’s bio
- Dr. Picard on Twitter
- Dr. Picard’s company, Empatica - https://www.empatica.com/ - The FDA-cleared Empatica Health Monitoring Platform provides accurate, continuous health insights for researchers and clinicians, collected in the real world
- Empatica Twitter
- Dr. Picard and her team have published hundreds of peer-reviewed articles across AI, Machine Learning, Affective Computing, Digital Health, and Human-computer interaction.
- Dr. Picard’s TED talk
Rosalind Picard
If you look back on the last century of scientific achievements, you might notice that most of the scientists we celebrate are overwhelmingly white, while scientists of color take a backseat. Since the Nobel Prize was introduced in 1901, for example, no black scientists have landed this prestigious award.
The work of black women scientists has gone unrecognized in particular. Their work uncredited and often stolen, black women have nevertheless contributed to some of the most important advancements of the last 100 years, from the polio vaccine to GPS.
Here are five black women who have changed science forever.
Dr. May Edward Chinn
Dr. May Edward Chinn practicing medicine in Harlem
George B. Davis, PhD.
Chinn was born to poor parents in New York City just before the start of the 20th century. Although she showed great promise as a pianist, playing with the legendary musician Paul Robeson throughout the 1920s, she decided to study medicine instead. Chinn, like other black doctors of the time, were barred from studying or practicing in New York hospitals. So Chinn formed a private practice and made house calls, sometimes operating in patients’ living rooms, using an ironing board as a makeshift operating table.
Chinn worked among the city’s poor, and in doing this, started to notice her patients had late-stage cancers that often had gone undetected or untreated for years. To learn more about cancer and its prevention, Chinn begged information off white doctors who were willing to share with her, and even accompanied her patients to other clinic appointments in the city, claiming to be the family physician. Chinn took this information and integrated it into her own practice, creating guidelines for early cancer detection that were revolutionary at the time—for instance, checking patient health histories, checking family histories, performing routine pap smears, and screening patients for cancer even before they showed symptoms. For years, Chinn was the only black female doctor working in Harlem, and she continued to work closely with the poor and advocate for early cancer screenings until she retired at age 81.
Alice Ball
Pictorial Press Ltd/Alamy
Alice Ball was a chemist best known for her groundbreaking work on the development of the “Ball Method,” the first successful treatment for those suffering from leprosy during the early 20th century.
In 1916, while she was an undergraduate student at the University of Hawaii, Ball studied the effects of Chaulmoogra oil in treating leprosy. This oil was a well-established therapy in Asian countries, but it had such a foul taste and led to such unpleasant side effects that many patients refused to take it.
So Ball developed a method to isolate and extract the active compounds from Chaulmoogra oil to create an injectable medicine. This marked a significant breakthrough in leprosy treatment and became the standard of care for several decades afterward.
Unfortunately, Ball died before she could publish her results, and credit for this discovery was given to another scientist. One of her colleagues, however, was able to properly credit her in a publication in 1922.
Henrietta Lacks
onathan Newton/The Washington Post/Getty
The person who arguably contributed the most to scientific research in the last century, surprisingly, wasn’t even a scientist. Henrietta Lacks was a tobacco farmer and mother of five children who lived in Maryland during the 1940s. In 1951, Lacks visited Johns Hopkins Hospital where doctors found a cancerous tumor on her cervix. Before treating the tumor, the doctor who examined Lacks clipped two small samples of tissue from Lacks’ cervix without her knowledge or consent—something unthinkable today thanks to informed consent practices, but commonplace back then.
As Lacks underwent treatment for her cancer, her tissue samples made their way to the desk of George Otto Gey, a cancer researcher at Johns Hopkins. He noticed that unlike the other cell cultures that came into his lab, Lacks’ cells grew and multiplied instead of dying out. Lacks’ cells were “immortal,” meaning that because of a genetic defect, they were able to reproduce indefinitely as long as certain conditions were kept stable inside the lab.
Gey started shipping Lacks’ cells to other researchers across the globe, and scientists were thrilled to have an unlimited amount of sturdy human cells with which to experiment. Long after Lacks died of cervical cancer in 1951, her cells continued to multiply and scientists continued to use them to develop cancer treatments, to learn more about HIV/AIDS, to pioneer fertility treatments like in vitro fertilization, and to develop the polio vaccine. To this day, Lacks’ cells have saved an estimated 10 million lives, and her family is beginning to get the compensation and recognition that Henrietta deserved.
Dr. Gladys West
Andre West
Gladys West was a mathematician who helped invent something nearly everyone uses today. West started her career in the 1950s at the Naval Surface Warfare Center Dahlgren Division in Virginia, and took data from satellites to create a mathematical model of the Earth’s shape and gravitational field. This important work would lay the groundwork for the technology that would later become the Global Positioning System, or GPS. West’s work was not widely recognized until she was honored by the US Air Force in 2018.
Dr. Kizzmekia "Kizzy" Corbett
TIME Magazine
At just 35 years old, immunologist Kizzmekia “Kizzy” Corbett has already made history. A viral immunologist by training, Corbett studied coronaviruses at the National Institutes of Health (NIH) and researched possible vaccines for coronaviruses such as SARS (Severe Acute Respiratory Syndrome) and MERS (Middle East Respiratory Syndrome).
At the start of the COVID pandemic, Corbett and her team at the NIH partnered with pharmaceutical giant Moderna to develop an mRNA-based vaccine against the virus. Corbett’s previous work with mRNA and coronaviruses was vital in developing the vaccine, which became one of the first to be authorized for emergency use in the United States. The vaccine, along with others, is responsible for saving an estimated 14 million lives.