Pregnant & Breastfeeding Women Who Get the COVID-19 Vaccine Are Protecting Their Infants, Research Suggests
Becky Cummings had multiple reasons to get vaccinated against COVID-19 while tending to her firstborn, Clark, who arrived in September 2020 at 27 weeks.
The 29-year-old intensive care unit nurse in Greensboro, North Carolina, had witnessed the devastation day in and day out as the virus took its toll on the young and old. But when she was offered the vaccine, she hesitated, skeptical of its rapid emergency use authorization.
Exclusion of pregnant and lactating mothers from clinical trials fueled her concerns. Ultimately, though, she concluded the benefits of vaccination outweighed the risks of contracting the potentially deadly virus.
"Long story short," Cummings says, in December "I got vaccinated to protect myself, my family, my patients, and the general public."
At the time, Cummings remained on the fence about breastfeeding, citing a lack of evidence to support its safety after vaccination, so she pumped and stashed breast milk in the freezer. Her son is adjusting to life as a preemie, requiring mother's milk to be thickened with formula, but she's becoming comfortable with the idea of breastfeeding as more research suggests it's safe.
"If I could pop him on the boob," she says, "I would do it in a heartbeat."
Now, a study recently published in the Journal of the American Medical Association found "robust secretion" of specific antibodies in the breast milk of mothers who received a COVID-19 vaccine, indicating a potentially protective effect against infection in their infants.
The presence of antibodies in the breast milk, detectable as early as two weeks after vaccination, lasted for six weeks after the second dose of the Pfizer-BioNTech vaccine.
"We believe antibody secretion into breast milk will persist for much longer than six weeks, but we first wanted to prove any secretion at all after vaccination," says Ilan Youngster, the study's corresponding author and head of pediatric infectious diseases at Shamir Medical Center in Zerifin, Israel.
That's why the research team performed a preliminary analysis at six weeks. "We are still collecting samples from participants and hope to soon be able to comment about the duration of secretion."
As with other respiratory illnesses, such as influenza and pertussis, secretion of antibodies in breast milk confers protection from infection in infants. The researchers expect a similar immune response from the COVID-19 vaccine and are expecting the findings to spur an increase in vaccine acceptance among pregnant and lactating women.
A COVID-19 outbreak struck three families the research team followed in the study, resulting in at least one non-breastfed sibling developing symptomatic infection; however, none of the breastfed babies became ill. "This is obviously not empirical proof," Youngster acknowledges, "but still a nice anecdote."
Leaps.org inquired whether infants who derive antibodies only through breast milk are likely to have a lower immunity than infants whose mothers were vaccinated while they were in utero. In other words, is maternal transmission of antibodies stronger during pregnancy than during breastfeeding, or about the same?
"This is a different kind of transmission," Youngster explains. "When a woman is infected or vaccinated during pregnancy, some antibodies will be transferred through the placenta to the baby's bloodstream and be present for several months." But in the nursing mother, that protection occurs through local action. "We always recommend breastfeeding whenever possible, and, in this case, it might have added benefits."
A study published online in March found COVID-19 vaccination provided pregnant and lactating women with robust immune responses comparable to those experienced by their nonpregnant counterparts. The study, appearing in the American Journal of Obstetrics and Gynecology, documented the presence of vaccine-generated antibodies in umbilical cord blood and breast milk after mothers had been vaccinated.
Natali Aziz, a maternal-fetal medicine specialist at Stanford University School of Medicine, notes that it's too early to draw firm conclusions about the reduction in COVID-19 infection rates among newborns of vaccinated mothers. Citing the two aforementioned research studies, she says it's biologically plausible that antibodies passed through the placenta and breast milk impart protective benefits. While thousands of pregnant and lactating women have been vaccinated against COVID-19, without incurring adverse outcomes, many are still wondering whether it's safe to breastfeed afterward.
It's important to bear in mind that pregnant women may develop more severe COVID-19 complications, which could lead to intubation or admittance to the intensive care unit. "We, in our practice, are supporting pregnant and breastfeeding patients to be vaccinated," says Aziz, who is also director of perinatal infectious diseases at Stanford Children's Health, which has been vaccinating new mothers and other hospitalized patients at discharge since late April.
Earlier in April, Huntington Hospital in Long Island, New York, began offering the COVID-19 vaccine to women after they gave birth. The hospital chose the one-shot Johnson & Johnson vaccine for postpartum patients, so they wouldn't need to return for a second shot while acclimating to life with a newborn, says Mitchell Kramer, chairman of obstetrics and gynecology.
The hospital suspended the program when the Food and Drug Administration and the Centers for Disease Control and Prevention paused use of the J&J vaccine starting April 13, while investigating several reports of dangerous blood clots and low platelet counts among more than 7 million people in the United States who had received that vaccine.
In lifting the pause April 23, the agencies announced the vaccine's fact sheets will bear a warning of the heightened risk for a rare but serious blood clot disorder among women under age 50. As a result, Kramer says, "we will likely not be using the J&J vaccine for our postpartum population."
So, would it make sense to vaccinate infants when one for them eventually becomes available, not just their mothers? "In general, most of the time, infants do not have as good of an immune response to vaccines," says Jonathan Temte, associate dean for public health and community engagement at the University of Wisconsin School of Medicine and Public Health in Madison.
"Many of our vaccines are held until children are six months of age. For example, the influenza vaccine starts at age six months, the measles vaccine typically starts one year of age, as do rubella and mumps. Immune response is typically not very good for viral illnesses in young infants under the age of six months."
So far, the FDA has granted emergency use authorization of the Pfizer-BioNTech vaccine for children as young as 16 years old. The agency is considering data from Pfizer to lower that age limit to 12. Studies are also underway in children under age 12. Meanwhile, data from Moderna on 12-to 17-year-olds and from Pfizer on 12- to 15-year-olds have not been made public. (Pfizer announced at the end of March that its vaccine is 100 percent effective in preventing COVID-19 in the latter age group, and FDA authorization for this population is expected soon.)
"There will be step-wise progression to younger children, with infants and toddlers being the last ones tested," says James Campbell, a pediatric infectious diseases physician and head of maternal and child clinical studies at the University of Maryland School of Medicine Center for Vaccine Development.
"Once the data are analyzed for safety, tolerability, optimal dose and regimen, and immune responses," he adds, "they could be authorized and recommended and made available to American children." The data on younger children are not expected until the end of this year, with regulatory authorization possible in early 2022.
For now, Vonnie Cesar, a family nurse practitioner in Smyrna, Georgia, is aiming to persuade expectant and new mothers to get vaccinated. She has observed that patients in metro Atlanta seem more inclined than their rural counterparts.
To quell some of their skepticism and fears, Cesar, who also teaches nursing students, conceived a visual way to demonstrate the novel mechanism behind the COVID-19 vaccine technology. Holding a palm-size physical therapy ball outfitted with clear-colored push pins, she simulates the spiked protein of the coronavirus. Slime slathered at the gaps permeates areas around the spikes—a process similar to how our antibodies build immunity to the virus.
These conversations often lead hesitant patients to discuss vaccination with their husbands or partners. "The majority of people I'm speaking with," she says, "are coming to the conclusion that this is the right thing for me, this is the common good, and they want to make sure that they're here for their children."
CORRECTION: An earlier version of this article mistakenly stated that the COVID-19 vaccines were granted emergency "approval." They have been granted emergency use authorization, not full FDA approval. We regret the error.
Why Aren’t Gene Editing Treatments Available Yet For People With Genetic Disorders? 
Lynn Julian Crisci, 40, is an actress, a singer-songwriter, and an ambassador for the U.S. Pain Foundation. She is also a Boston Marathon bombing survivor. Crisci has a genetic disorder called Ehlers-Danlos syndrome (EDS), which has magnified the impact of the traumatic brain injury she sustained as a result of the attack that occurred almost five years ago. Having EDS means that her brain tissue is weaker and more prone to injury.
"I would love to learn more about gene editing and the possibilities of using it to lessen the symptoms of EDS, or cure it completely."
"EDS is a genetic tissue disorder that forces the body to make defective collagen," Crisci told LeapsMag. Since collagen is the main component of connective tissue (bones, blood vessels, the gastrointestinal tract, skin, cartilage, etc.), and is the most abundant protein in mammals, EDS can affect virtually every part of the body. "This results in widespread joint pain, usually due to hypermobility, sometimes along with digestive issues such as inflammatory bowel disease, and prolapsed organs."
If life was difficult with Ehlers-Danlos syndrome alone, the addition of the brain injury has made Crisci's life feel unbearable at times. Amidst her week's back-to-back doctor's visits, Crisci said that she would "love to learn more about gene editing and the possibilities of using it to lessen the symptoms of Ehlers-Danlos syndrome, or cure it completely."
With all of the excitement these days around CRISPR, a precise and efficient way to edit DNA that has taken the world by storm, such treatments seem tantalizingly within reach. But is it fair to present the hope of such cures to those with life-limiting genetic disorders?
"From the experience that we've had from gene therapy — we're 20, almost 30 years past some of the initial gene therapy stuff — and there's still not a huge number of applications for it," said Scott Weissman, founder of Chicago Genetic Consultants, a company that provides genetic counseling services to patients. "Unfortunately, we have to wait and see if this is something that's truly viable, or if it's really just hype."
"I expect five years from now we'll look back and say, 'Wow, we were just scratching the surface.'"
Defining Our Terms
The terms "gene therapy" and "gene editing" are often used interchangeably, but not everyone agrees with this usage.
According to Editas Medicine, a leader in CRISPR technology, gene therapy involves the transfer of a new gene into a patient's cells to augment a defective gene, instead of using drugs or surgery to treat a condition. After a teenager's death in 1999 effectively shut down gene therapy research in the U.S., subsequent studies helped the field make a comeback, and the first such treatment for an inherited disease was approved by the FDA just a few weeks ago, for a rare form of vision loss. Called Luxturna, it is for treatment of patients with RPE65-mediated inherited retinal disease (IRD).
Since those with RPE65-mediated IRD typically become blind in childhood and have no pharmacologic treatment options, the FDA's approval of Luxturna is "a significant moment for patients," said Jeffrey Marrazzo, the chief executive officer of the company behind the product, Spark Therapeutics. Two other gene therapy treatments were also approved in the last five months, both for specific cancers.
Gene editing, on the other hand, refers to a group of technologies that enables scientists to precisely and directly change an organism's genes by adding, removing, or altering particular segments of DNA. Gene editing tools include Zinc Finger Nucleases (ZFNs), Transcription Activator-Like Effector Nucleases (TALENs), and CRISPR/Cas9. The first treatment using ZFNs happened in November in California, when a 44-year-old man with a metabolic ailment called Hunter syndrome was injected with gene editing tools. Results are not yet known.
Dr. David Valle, director of the Institute of Genetic Medicine at Johns Hopkins, said that gene therapy's "significant therapeutic misadventures" have actually been beneficial. They've helped us learn to "be rigorous in our thinking about what we can do and what we can't do with CRISPR" and other gene editing tools.
"It appears like we are really beginning to have, for the first time, some meaningful and good results from gene therapy — it's moving into the clinic now in a meaningful way," Valle said. "I expect five years from now we'll look back and say, 'Wow, we were just at this point in 2017 — we were just scratching the surface.'"
Over 2300 gene therapy clinical trials are planned, ongoing, or have been completed so far. As for gene editing, no treatments are commercially available anywhere in the world. The expectation, however, is that many treatments that are "currently in or soon to enter clinical trials will come up for approval in coming years," according to a November 2016 report by the American Society of Gene & Cell Therapy.
CRISPR Therapeutics of Cambridge, Massachusetts will begin a European gene editing trial this year, with the hopes of creating a treatment for beta thalassemia, an inherited blood disorder. The company will also request approval from the FDA to begin a clinical trial using CRISPR for sickle-cell disease. And Stanford University School of Medicine researchers are planning a similar CRISPR clinical trial for sickle-cell disease. They hope to begin their trial in 2019.
Jim Burns, the president and chief executive officer of Casebia Therapeutics, told Leapsmag that the company will start animal research this year using CRISPR to treat autoimmune diseases, hemophilia A, and retinal diseases. They expect to begin clinical research in humans in 2019 or 2020. [Disclosure: Casebia Therapeutics is a novel joint venture between CRISPR Therapeutics and Leapsmag's founder, Leaps by Bayer, though Leapsmag is editorially independent of Bayer.]
Efforts are well underway to take genome-targeted treatments from the scientist's bench to the patient's bedside.
The Technology Isn't There Yet
Unlike germline gene editing — when egg and sperm cell DNA is edited in an embryo — somatic cell gene editing in adults is not very controversial, because the edits are not heritable. Since somatic cells contribute to the various tissues of the body but not to eggs or sperm cells, changes made to somatic cells are limited to the treated individual.
The number one reason that gene therapy and gene editing treatments are not yet widely available to the adult population is that the technology is not advanced enough. But it's getting there. Efforts are well underway to take genome-targeted treatments from the scientist's bench to the patient's bedside — especially in the case of monogenic diseases.
Roughly 10,000 genetic illnesses are monogenic, meaning that they result from a disease-causing variant in a single gene. Some monogenic diseases that have gene editing treatments currently in development for use in clinical trials include cystic fibrosis, Huntington's disease, Tay-Sachs disease, and sickle cell anemia.
Marrazzo of Spark Therapeutics told LeapsMag that his company is working on gene therapies for monogenic diseases that affect the eye, like the retinal disease that Luxturna targets, as well as neurodegenerative and liver diseases.
But most illnesses are polygenic, meaning that they result from multiple gene mutations that have a combined influence on disease progression. Polygenic diseases, like high blood pressure and diabetes, would therefore be more challenging to treat with genome-targeted interventions. As a result, most research is currently focused on monogenic diseases.
"We don't really know how to target the gene editing to a specific organ in the body once it's fully developed and matured."
A major hurdle of gene editing is the risk of off-target effects. Editing the genome "can have unpredictable effects on gene expression and unintended effects on neighboring genes," wrote Morgan Maeder and Charles Gersbach in a March 2016 article in Molecular Therapy. One such unintended effect is the development of leukemia when a new gene unintentionally activates a cancer gene.
And since there are roughly 37 trillion cells in the adult human body, getting the gene editing machinery to enough cells or target tissues to create a lasting and significant change is a daunting task.
"We don't really know how to target the gene editing to a specific organ in the body once it's fully developed and matured," said Weissman, the genetic counseling expert. If you take an adult patient with known BRCA1 or BRCA2 mutations, for example, how do you then "get the [gene editing] system in the breast so that it accurately cuts out the mutation in every single breast cell that could potentially turn into breast cancer, or in every single ovarian cell that could turn into ovarian cancer? We don't know how to target it like that, and I think that's the biggest reason you're not seeing it more somatically at this point in time."
Approval and Access
Debra Mathews, assistant director for science programs for the Johns Hopkins Berman Institute of Bioethics, told LeapsMag that pre-existing regulatory frameworks surrounding gene therapy have been sufficient for addressing ethical and regulatory concerns surrounding gene editing. A bigger concern, she said, centers around access to future genome-targeted treatments.
"We know more about the genetics of Caucasian populations than other populations," Mathews explained, due to how genomic data is gathered. This "could lead to problems not just of financial but of biological access to new therapies." In other words, she said, "if you're of European ancestry, there may be a greater chance that there's a relevant genetically-targeted therapy for you than if you're of non-European ancestry."
Ensuring that genome-targeted treatments are accessible to all will require increased cooperation and data-sharing among key stakeholders around the world, as well as increased public engagement that is inclusive of a wide range of voices.
"It's important to be realistic in our predictions to the public."
The Coming Wave of Gene Editing Treatments
Ehlers-Danlos syndrome alone has 13 monogenic subtypes, each with its own genetic basis and set of clinical criteria. Though several of the gene mutations causing EDS subtypes have been identified, the genetic basis for the most common subtype that Lynn Julian Crisci has — hypermobile EDS — remains unknown. What this means, according to Valle, the doctor from Johns Hopkins, is that a gene therapy or gene editing approach "really cannot be contemplated because we don't know what we're trying to fix" yet. This is the case for many genetic illnesses.
Efforts are ongoing in gene discovery by organizations such as the Baylor-Hopkins Center for Mendelian Genomics, of which Valle is the principal investigator. "Our objective," he said, "is to identify the genes and variants responsible" in monogenic disorders.
While Valle is optimistic about the coming wave of commercially available gene therapy and gene editing treatments, he also thinks that "it's important to be realistic in our predictions to the public." As eager as physicians are to offer cures to their patients, "we have to make sure that we're rigorous in our thinking and our ideas are well-buttressed with results."
Estimates vary for how long Crisci and others with genetic illnesses will have to wait for genome-targeted treatment options. Depending on the illness, viable gene editing treatments could hit the market within the next ten years. Though patients have already waited a long while, the revolutionary technology allowing us to fix nature's mistakes could make up for lost time and lost hope.
A Drug Straight Out of Science Fiction Has Arrived
Steve, a 60-year-old resident of the DC area who works in manufacturing, was always physically fit. In college, he played lacrosse in Division I, the highest level of intercollegiate athletics in the United States. Later, he stayed active by swimming, biking, and running--up until something strange happened around two years ago.
"It was hard for me to even get upstairs. I wasted away."
Steve, who requested that his last name be withheld to protect his privacy, started to notice weakness first in his toes, then his knees. On a trip to the zoo, he had trouble keeping up. Then some months later, the same thing happened on a family hike. What was supposed to be a four-mile trek up to see a waterfall ended for him at the quarter-mile mark. He turned around and struggled back to the start just as everyone else was returning from the excursion.
Alarmed, he sought out one doctor after the next, but none could diagnose him. The disabling weakness continued to creep up his legs, and by the time he got in to see a top neurologist at Johns Hopkins University last January, he was desperate for help.
"It was hard for me to even get upstairs," he recalls. "I wasted away and had lost about forty-five pounds."
The neurologist, Dr. Michael Polydefkis, finally made the correct diagnosis based on Steve's rapid progression of symptoms, a skin and nerve biopsy, and a genetic test. It turned out that Steve had a rare inherited disease called hereditary transthyretin amyloidosis. Transthyretin is a common blood protein whose normal function is to transport vitamins and hormones in the body. When patients possess certain genetic mutations in the transthyretin gene, the resulting protein can misfold, clump and produce amyloid, an aggregate of proteins, which then interferes with normal function. Many organs are affected in this disease, but most affected are the nervous system, the GI tract, and the heart.
Dr. Michael Polydefkis, Steve's neurologist at Johns Hopkins Bayview Medical Center in Baltimore, MD.
(Courtesy of Dr. Polydefkis)
For the 50,000 patients like Steve around the world, the only treatment historically has been a liver transplant—a major, risky operation. The liver makes most of the transthyretin in a person's body. So if a person who carries a genetic mutation for a disease-causing form of transthyretin has their liver transplanted, the new liver will stop making the mutant protein. A few drugs can slow, but do not stop the disease.
Since it is a genetic condition, a regular "drug" can't tackle the problem.
"For almost all of medicine from the 18th century to today, drugs have been small molecules, typically natural, some invented by humans, that bind to proteins and block their functions," explains Dr. Phillip Zamore, chair of the department of Biomedical Sciences at the University of Massachusetts Medical School. "But with most proteins (including this one), you can't imagine how that would ever happen. Because even if it stuck, there's no reason to think it would change anything. So people threw up their hands and said, 'Unless we can find a protein that is "druggable" in disease X, we can't treat it.'"
To draw a car analogy, treating a disease like Steve's with a small molecule would be like trying to shut down the entire car industry when all you can do is cut the power cord to one machine in one local factory. With few options, patients like Steve have been at a loss, facing continual deterioration and disability.
"It's more obvious how to be specific because we use the genetic code itself to design the drug."
A Radical New Approach
Luckily, Dr. Polydefkis knew of an experimental drug made by a biotech company that Dr. Zamore co-founded called Alnylam Pharmaceuticals. They were doing something completely different: silencing the chemical blueprint for protein, called RNA, rather than targeting the protein itself. In other words, shutting down all the bad factories across the whole car industry at once – without touching the good ones.
"It's more obvious how to be specific," says Dr. Zamore, "because we use the genetic code itself to design the drug."
For Steve's doctor, the new drug, called patisiran, is a game changer.
"It's the dawn of molecular medicine," says Dr. Polydefkis. "It's really a miraculous development. The ability to selectively knock down or reduce the amount of a specific protein is remarkable. I tell patients this is science fiction that is now becoming reality."
A (Very) Short History
The strategy of silencing RNA as a method of guiding drug development began in 1998. Basic research took six years before clinical testing in humans began in 2004. Just a few months ago, in November, the results of the first double-blind, placebo-controlled phase III trials were announced, testing patisiran in patients--and they surpassed expectations.
"The results were remarkably positive," says Dr. Polydefkis. "Every primary and secondary outcome measure target was met. It's the most positive trial I have ever been associated with and that I can remember in recent memory."
FDA approval is expected to come by summer, which will mark the first official sanction of a drug based on RNA inhibition (RNAi). Experts are confident that similar drugs will eventually follow for other diseases, like familial hypercholesterol, lipid disorders, and breathing disorders. Right now, these drugs must get into the liver to work, but otherwise the future treatment possibilities are wide open, according to Dr. Zamore.
"It doesn't have to be a genetic disease," he says. "In theory, it doesn't have to be just one gene, although I don't think anyone knows how many you could target at once. There is no precedent for targeting two."
Dr. Phillip Zamore, chair of the RNA Therapeutics Institute at the University of Massachusetts Medical School.
(Courtesy of Dr. Zamore)
Alnylam, the leading company in RNAi therapeutics, plans to strategically design other new drugs based on what they have learned from this first trial – "so with each successive experience, with designing and testing, you get better at making more drugs. In a way, that's never happened before...This is a lot more efficient of a way to make drugs in the future."
And unlike gene therapy, in which a patient's own genetic code is permanently altered, this approach does not cause permanent genetic changes. Patients can stop taking it like any other drug, and its effects will vanish.
How Is Steve?
Last February, Steve started on the drug. He was granted early access since it is not yet FDA-approved and is still considered experimental. Every 21 days, he has received an IV infusion that causes some minor side effects, like headaches and facial flushing.
"The good news is, since I started on the drug, I don't see any more deterioration other than my speech."
So far, it seems to be effective. He's gained back 20 pounds, and though his enunciation is still a bit slurred, he says that his neuropathy has stopped. He plans to continue the treatment for the rest of his life.
"The good news is, since I started on the drug, I don't see any more deterioration other than my speech," he says. "I think the drug is working, but would I have continued to deteriorate without the drug? I'm not really sure."
Dr. Polydefkis jumps in with a more confident response: "If you ask me, I would say 100 percent he would have kept progressing at a fairly rapid pace without the drug. When Steve says the neuropathy has stopped, that's music to my ears."
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.