Summary
This episode explores microchimerism—the presence of fetal cells in pregnant people's bodies that can persist for decades. Researchers are investigating whether these cells help heal injuries and fight disease, or contribute to autoimmune disorders and cancer, though definitive answers remain elusive due to technical and funding limitations.
Insights
- Microchimerism is bidirectional and multigenerational, creating complex cellular relationships that may never be fully untangled, limiting research clarity
- Fetal cells demonstrate protective healing properties in animal models but correlative evidence in humans remains inconclusive, requiring careful interpretation
- Reproductive health research is significantly underfunded relative to its prevalence and impact, slowing scientific progress on fundamental biological questions
- The same fetal cells may simultaneously help and harm—potentially fighting cancer while triggering autoimmune responses—making causation difficult to establish
- Technical barriers like tracking individual cells among trillions and ethical constraints on human experimentation create fundamental research limitations
Trends
Growing recognition that pregnancy involves complex cellular exchanges with long-term health implications beyond traditional obstetric focusIncreased interest in stem cell therapies derived from understanding natural healing mechanisms in microchimerismEmerging research linking reproductive history to autoimmune disease risk, particularly in womenShift toward studying pregnancy as a dynamic immunological event rather than a static conditionRecognition of funding gaps in reproductive biology as a barrier to understanding fundamental human health mechanisms
Topics
Microchimerism and fetal-maternal cell exchangeAutoimmune disease etiology and pregnancyStem cell biology and regenerative medicineCancer and fetal cell involvementWound healing and tissue repair mechanismsPregnancy immunologyReproductive health research fundingBiomedical research methodology in humans vs. animal modelsIntergenerational cellular inheritanceHeart health during pregnancy
People
Amy Boddy
Expert researcher explaining microchimerism biology and fetal cell mechanisms in maternal bodies
Lee Nelson
Pioneer researcher from 1990s studying microchimerism and autoimmune disease connections; provided extensive research...
Bird Pinkerton
Episode host and reporter who interviewed mother about microchimerism and researched fetal cell science
Ann Bird Platt
Bird Pinkerton's mother; guest participant discussing personal experience with microchimerism
Quotes
"It's possible that my cells are just the equivalent of that. Like you have some tiny little cell-sized chachkies of me inside of you."
Bird Pinkerton•Early in episode
"Researchers don't know. It seems like, you know, maybe something like a parent-child relationship. Some of the things that these cells might be doing might be good. Some of them might be somewhat less good."
Bird Pinkerton•Mid-episode
"These cells are both part of the parent's self and also genetically foreign. So maybe, and again, I'm emphasizing maybe, this could be contributing to autoimmune diseases."
Bird Pinkerton•Autoimmune disease discussion
"It's a couple of cells in a million. And so it's kind of like looking for a needle in the haystack if the needle looked like a lot like hay, right?"
Bird Pinkerton (paraphrasing Lee Nelson)•Research challenges section
"There's something about it that, like there might be things that we'd never fully understand here, right? Like we are potentially never going to be able to completely untangle the way that like my cells and my sister cells and the cells from your miscarriages have affected your body."
Bird Pinkerton•Conclusion
Full Transcript
Dell PCs with Intel inside are built for the moments you plan, and the ones you don't. For the time you forgot your charger at the gate. Passengers, we are now on our initial ascent. Or when you're bouncing between projects like a ping-pong ball. We build PCs with long-lasting battery life so you're not scrambling for a charger. And built in intelligence so you can stay focused on whatever you're doing. Dell Technologies, built for you. Dell.co.uk forward slash Dell PCs. Support for the show comes from Odoo. Running a business is hard enough. So why make it harder with a dozen different apps that don't talk to each other? Introducing Odoo. It's the only business software you'll ever need. It's an all-in-one fully integrated platform that makes your work easier. CRM, accounting, inventory, e-commerce and more. And the best part? Odoo replaces multiple expensive platforms for a fraction of the cost. That's why over thousands of businesses have made the switch. So why not you? Try Odoo for free at odoo.com. That's odoo.com. Okay, so I am recording. Do you want to just first start by, can you say your name and how you know me? My name is Ann Bird Platt and I am Bird Pinkerton's mother. That's my mom. And I called my mom after I found out this fascinating thing. Basically that some cells from my body are probably hanging out inside of her body and have likely been there for three decades, like ever since she carried me in her womb. And as I told her, those cells are genetically me. It seems like some of them might have stuck around in your body and become a part of you. And I am curious what you make of that. You can't have the bag! You want to use that quote? You can't have the bag! Thanks, mama. Oh my. Great. Thank you for telling me how to do my job. So my plan here was to explain to my mom very briefly sort of what those cells could be doing inside her and what similar cells are doing to parents all over. And that plan went without a hitch. Can you, I mean, now, since you're helping me out, can you ask me what are they doing inside my body? What are these cells doing inside my body? Can I ask it as a statement? What do you mean, can you ask it as a statement? I hope these cells are behaving themselves. You know, they're playing nicely with my cells. Well, I mean, I'm just kidding. Here's the fun twist. Researchers don't know. It seems like, you know, maybe something like a parent-child relationship. Some of the things that these cells might be doing might be good. Some of them might be somewhat less good. Some of them might be totally neutral. And researchers just don't know. Define less good. All right. Well, let's get into it. Do you want me to tell you a little bit about all like, okay, so I'm going to, I wasn't actually, I was just going to walk you through that intro, but why don't I just tell you the whole episode and see what happens. Okay. Do you have something? No. I. You definitely, something is happening. It's Chris. Can you just put your phone on silent? Yes, I can put my phone on silent. Thank you. It's on silent. It's unexplainable. I'm Bird Pinkerton. And we originally aired this episode a few years ago when we did a series on pregnancy and parenting. But we recently had a bunch of people on the team become parents. So I've been thinking about pregnancy a lot. And especially about the idea that even though pregnancy is one of the most common experiences on earth, right? This thing that we all participate in in order to be alive, pregnancy is still very mysterious. It's mysterious in ways that are amazing and inspiring, obviously, but also in ways that can hurt parents or at least confuse them. And so the story that I was telling my mom is kind of this perfect example of a lot of the things I learned about pregnancy over the course of my reporting. Like it has got a wonder element, but it also has an element of just the frustrating reality that we are still very, very far from satisfying answers. Alright, so let's just start with the basics here. I just pulled like idea of my giving you my cells, right? It's actually a subset of something called chimerism, which you know what a chimera is, right? Yes, I do. You want to describe that for me? Well, it's like a replication of the real thing. Not exactly. Chimer is like a mythical creature from Greek myth. It has like a lion head, a snake tail, and a goat body. It's like a griffin's a chimera, a sphinx, a manticore. It's the composite, right? Let the record show that my mother did know what a chimera was and was unfairly put on the spot. Doesn't sound like your mother knew what a chimera was. So that is a chimera in myth. But to understand a chimera in biology and what it has to do with pregnancy, I've reached out to Amy Boddy, who is a biologist at UC Santa Barbara. And Amy says that in biology, the definition of chimera is a little bit broader than in myth. It's multiple individuals existing in one host body. And so she was telling me that basically whenever you have a living thing that's made up of pieces of more than one individual, that's a chimera. So you can find them in plants, you can find them in animals, you can even find them in humans. So this is not like if you see organ transplantation or something like that, where you have a large tissue, right? That's from someone that is a completely different individual. You can consider that person a chimera. So this is not like the goat, lion, hybrid version of a chimera, right? It's just bits of two genetically different people. So technically, Mama, Amy was telling me that this process that you and I went through, where some of my cells left my body, kind of went into your body, that is considered chimerism on like a tiny scale. So they literally call it microchimera because you just have like a few cells. So cells from me, cells from my sister Chloe, and also potentially from any like miscarriages that you might have had. So how many cells do I have from you? So according to Amy, it can be infrequently as one in a million cells, but we have 30 trillion cells in our body. So a trillion is like a million million, right? So if you're doing the math, could potentially be 30 million cells from me floating around in you. Oh. Yeah, but so some people have fewer. There are actually, there are usually more during pregnancy and then your immune system kind of gets rid of a lot of them. But around the 1990s is when researchers started to realize that some cells were really sticking around in the parent long term, like potentially for the parent's whole life, which was surprising, right? And a lot of these cells are probably stem cells. So do you know what a stem cell is? Yeah, after my implosion with chimeria, I am not hatcheting again. Okay, so a stem cell is like the really basic cells that then develop into other tissues. So they're kind of like a like jack of all trades flexible cells. I can turn into any kind of cell. So you can basically imagine like the fetus has these these flexible cells, right? And then some of those cells travel into the placenta, which Amy was telling me is kind of like the main connector between the fetus and the parent. It's this super highway. So the fetus's cells sort of travel along this highway into the parent's body, hitching a ride in the circulatory system probably. And they finish their road trip eventually in the heart, say, or the lungs or the brain sort of all over the body. And then they can reshape themselves into a heart cell or a lung cell or a brain cell, whatever they're around and kind of braid themselves into that tissue. So they're doing work in the parent's body, even though genetically they're different from the cells around them. I'm intrigued, but I'm also puzzled. It basically opens up more questions than it even begins to answer. Welcome to the show. So starting around the 1990s, these researchers were sort of like, all right, like what is going on here? Like if these cells are sticking around and becoming part of the body, are they affecting it in some way? Like what are they doing? We don't know, but we have some ideas. First of all, Amy told me that it is very possible that at least potentially they are doing nothing. I have to admit it, even though I think there are some functional properties of these cells, but they could just be hanging out. Like it is possible that my cells are just like the chachkies that you love to collect, right? Like your little figurines that don't really do anything. They're just kind of there. It's possible that my cells are just the equivalent of that. Like you have some tiny little cell-sized chachkies of me inside of you. I don't do like little things anymore. I bought this huge piece of granite the other day in Bern, and I liked it all the way home, which was kind of silly. You bought granite? Like you can find granite on the ground. Well, but this was polished. Anyway, keep going. So again, there is a possibility that these cells are just hanging out like polished granite. But researchers have some good reasons to think that these cells are potentially doing other things. There are some studies that show that these cells actually help the host body. And so there's ideas out there that, yeah, this is a good feature to have. So for example, there have been studies to look at if someone has a C-section and they look at the tissue in the C-section. They found cells from the baby in the parent's scar tissue, essentially. Suggesting that they are there helping heal the gestational parent's body. And again, it's possible that they're just sort of randomly there, right? Because as Amy was saying, like these studies in humans aren't super firm evidence, because we don't know what they would be doing to heal a body. It's not clear that there are necessarily lots more fetal cells like in the scar site than anywhere else in the body. And that's maybe one of the biggest criticisms of they're just there. There's a few of them. You're just trying to find a purpose to the randomness of cells there. But if you just sort of step away from humans for a second, there is some more definitive research that has been done in mice. So in mice, they'll breed female mice with these special males so that some of their fetuses can create cells that fluoresce. It's like a glow-in-the-dark feature. And then the researchers can sort of dissect the mice or use machines to sort of track these glow-in-the-dark mouse fetus cells as they move through the mouse parent body. If a mouse gets an ear injury, the fetal cells will migrate up to the tissue. It seems like they're primed to be able to go in and kind of help recover and heal the maternal body. Huh. Which is cool. That's cool. And again, like something like that could also be happening in other mammals, including humans. So it's not just sort of like C-section scars, healing injuries. There's also been some research on how these cells that the parent gets from their fetus could potentially help with heart health. There was a mouse model where the heart was injured and they saw these cells, these fetal cells, migrating to the injury specializing in helping repair. So this is in mice, but it would actually help explain a phenomenon the doctors have seen in humans, which is basically like a lot of pregnant people develop heart issues. So your heart is actually doing like a huge workout during pregnancy. This will be no surprise to you, but you know, it's pumping a lot of blood. There's just like more of you and your body is working a lot harder. And so researchers have actually compared it to athletes who do long-distance sports. So you could just be pregnant and be like, I'm basically an endurance athlete. No wonder I hated it. But because the heart is doing this, this sort of nine month long workout, it makes sense that a lot of pregnant people develop problems with their heart during this time. What's interesting is that sometimes these problems just kind of fix themselves. Like they go away and researchers aren't totally sure why. And some are wondering if the cells from the fetus actually help fix things. Like if the cells from the fetus are traveling to the heart and giving it some kind of boost that could explain the sort of heart healing that is happening here. So it's quite fantastic, I think, in thinking about the coolest, weirdest biology. And again, like this is just one example of the ways that researchers think that these cells could be helping a parent's body sort of heal or fix issues, right? So maybe, you know, my cells at some point helped heal something in you as well. I think your cells need to get the right together. Let's get going here. Okay, I'll work on it. Nothing wrong with your heart, but I'll work on curing your various other ailments and diseases. Sorry. Sorry, I've been such a disappointment to you. You have not been a disappointment. Your cells are just, you know, let's get open. This feels like a perfect transition to the next thing here, which is that sometimes the parent fetus cell relationship becomes strained in certain ways. Like any communication between parent and child. It's not all sort of heart healing and scar knitting. Sometimes the cells from the kid can be somewhat obnoxious. This is the playing less well with others. Yes. So up next, how these cells might actually play a role in a whole range of pretty serious diseases. Dell PCs with Intel inside are built for the moments you plan and the ones you don't. For the time you forgot your charger at the gate. Passengers, we are now on our initial ascent. Or when you're bouncing between projects like a ping-pong ball. We build PCs with long lasting battery life so you're not scrambling for a charger. And built in intelligence so you can stay focused on whatever you're doing. Dell Technologies, built for you. Dell.co.uk forward slash Dell PCs. Support for the show comes from Odoo. Running a business is hard enough. So why make it harder with a dozen different apps that don't talk to each other? Introducing Odoo. It's the only business software you'll ever need. It's an all-in-one fully integrated platform that makes your work easier. CRM, accounting, inventory, e-commerce and more. And the best part? Odoo replaces multiple expensive platforms for a fraction of the cost. That's why over thousands of businesses have made the switch. So why not you? Try Odoo for free at odoo.com. That's odoo.com. We are about to see millionaires, billionaires and yes, probably even the world's first trillionaire created overnight. And yes, it's that guy. This is the chainsaw for bureaucracy. Chainsaw. But all the tech bros who are going to make all the money, they need our money way more than we need their products. And we're going to remind you why on today's Explained from Vox. So, mama. When I was in your womb, I gave you a bunch of my cells. This happens whenever there's a fetus inside a pregnant person for a while. And in this exchange, Amy Boddy says that there are trade-offs. It might be helpful during pregnancy. It might be helpful in the postpartum period, but long term, there could be some trade-offs where actually at some point it can lead to health complications. And one of the main complications that researchers have been exploring is related to autoimmune disease. Wow. So, like, to be really clear from the get-go, right, like this is all very much theoretical, right? It's something researchers are still trying to figure out. So, I would not want anyone with sort of an autoimmune disease to immediately assume that it comes from microchromera or this, like, exchange of cells, right? But basically, the way that Amy explained it to me is that we have this immune system, and its whole job is to sort of cruise around, check up on various cells, and say, like, is this me? Typically, your body recognizes cells by specific markers on your cell that says, you know, like, hey, I am me. And it leaves those cells alone. But then if it comes across cells that don't look like itself, then my immune system might say, nope, let's get rid of this. But in an autoimmune disorder, the immune system kind of goes haywire, right? Like, it starts attacking cells that are part of the body, that are part of itself in some way. And that leads to sort of the swelling, the pain, tiredness, like a whole bunch of different issues that are associated with autoimmune disorders. And so the way that this is potentially linked to microchromera is it turns out that people who have carried fetuses at some point in their lives do seem to be at higher risk for autoimmune diseases. The data that we have now focuses on women, but it shows that these diseases are significantly more likely to affect women as compared to men. And some studies have found that the chances of getting some of these diseases actually increases after women's reproductive years. So researchers were kind of looking at microchromera, and they were thinking like, okay, people who are getting pregnant are bringing kind of foreign cells into themselves that look a lot like them. Because usually half our DNA comes from each of our parents. So if these cells come in, they become part of the body, sort of part of the tissue. And then down the line, one scenario is that they do something that the body cells wouldn't usually do, right? Something more unique to the kid's cells. So maybe, for example. They're expressing a protein you've never seen before. Then your immune system might say, hey, that's not self. We need to go ahead and get rid of this. And that can, you know, elicit an autoimmune response. I don't know if we can call it autoimmune because that means self, right? Like, is it autoimmune? Because it's not attacking the self. It's attacking these foreign cells. And that's kind of the whole problem here, right? Like, these cells are both part of the parent's self and also genetically foreign. So maybe, and again, I'm emphasizing maybe, this could be contributing to autoimmune diseases. Like, maybe these foreign but not so foreign cells are why the body starts attacking itself. And there have been a few studies to sort of look at people with autoimmune diseases to look for proof that this might be happening. There's a few different studies looking at individuals with autoimmune disease and they find these fetal cells in the tissue. But once again, like, these are mostly sort of correlations. Like, we saw these cells and we saw this problem. Maybe they're related. We don't know the root cause. We don't know if these individuals would have gone on to get autoimmune diseases anyways and the cells again just happened to be there. So like, there's still work to be done here to sort of tease this relationship out and figure out what's going on. But it is sort of one way, at least, that people think that some of these sort of cells from, like, fetuses could be causing issues. Okay. I am fascinated by this. I wish there were more information. But what an interesting possibility? I think so too. Right? So there's this possibility, this possibility that they're involved in autoimmune diseases. And then the other possibility, which you are not going to like, is that these microchimera might also play a role in cancer. So basically, cancer is almost one of the best examples of maybe this is helpful, maybe this is harmful. Like, right now it's just kind of deeply confusing. Amy was saying she actually got interested in microchimera when she was studying breast cancer. So she was sort of like reading through these papers. And some women had higher amounts of fetal cells in their body and were diagnosed with cancer. Which would suggest that there could be some kind of a connection again, or like a correlation, right? Like more cells from the fetus, more cancer potentially. But then there's other papers. This is where it gets really confusing. There's other studies showing that no, actually, those cells might be in there trying to help fight the cancer and actually these cells are protective. And so it's a big like, we don't know what they're doing. Are they fighting the tumor? Are they making, you know, the immune system more aggressive and making this cancer worse? And we don't know the answer to that. So again, there are a lot of questions here, right? But if we can figure this stuff out, like if we can figure out exactly the effects that microchimera have on our body in terms of cancer, or also autoimmune diseases, like that could potentially be huge, right? Amy was saying that maybe we could figure out if people are high risk for certain issues and help them early, for example. The other exciting thing is some people are, again, seeing these potential fetal cells helping with wound healing. And the thought is that it could be a therapy, as well, providing a boost of stem cells to actually help fight a disease or help heal. Right now, because this is all such a mystery, like we're still a very long way away from these kinds of applications, right? Which I guess kind of just left me wondering why, right? Like why do we still have so many questions instead of answers here and know so little? That is a good question. Lee Nelson agrees with you. That's a good question. Lee Nelson is actually one of the researchers that I mentioned before who first started diving into microchimera in the 1990s. And she's been doing a lot of work for many decades on the autoimmune stuff specifically. So I asked her, essentially, like, why we are still so far from microchimera. And basically, we are still so far from answers. The most direct two answers to that are technical. So it's the techniques. And the other one is funding. Reproductive health in general is very underfunded. But this work is also just very hard from a technical perspective. The big challenge is very simple. All these little chimerical cells that are very hard to track. And, you know, you can put tracers in mice, like we mentioned before, but mice are not humans. Like mouse pregnancy just looks different than human pregnancy, which could lead to different effects. I mean, routinely mice are multiple gestations. They're routinely having, like, eight pups all at the same time, for example. I don't know anybody that's had eight or nine kids. And meanwhile, you can't, like, inject human fetuses with glow in the dark tracers or cut up human parents in the same way as mice to see what's going on. And so as a result, when you're looking at some of these cells in human tissue, you can't really know both where it came from and where it went to and kind of everything about it. And then even if you do have sort of some tissue that you're looking at from a human, finding these cells isn't easy, right? It's a couple of cells in a million. And so it's kind of like looking for a needle in the haystack if the needle looked like a lot like hay, right? Because it's actually got half the hay's DNA. And then one extra wrinkle that I talked about with both Leigh and Amy, but which I've sort of been saving for the end, is that microchimerism isn't just about fetuses passing cells to their parents. It's actually a lot more complicated because it goes both ways. So not only am I kind of giving you my cells, but when I was in your womb, you gave me some of your cells as well. Of course. Which means that you're not just sort of a chimera of me and my sister Chloe and any miscarriages that you might have had. You also have my grandmother, Muddy's cells, swimming around inside of you as well. That makes perfect sense. How far back to sick of? So it is also possible that your mom, so my grandmother, gave you some of your grandmother's cells. So any researcher sort of looking, Mama, at your tissue would be saying, is this cell from Ann Bird Platt? Or is it from her daughter Chloe or her daughter Bird or her mother or her grandmother or a miscarriage she had? Or like what? And so Amy says it's just hard to parse. So we've been talking very simply about this because it is so complex that we, our minds can't even wrap around the fact that there's actually multiple generations happening all at once. And so studying microchimera is so hard because you have to find just like a few cells in a million untangle this whole intergenerational jumble and then figure out like what those cells are doing, what they're up to. And that's part of why this research is going so slowly. You're getting these like two of, you know, a thousand piece puzzle, right? You're like, I think it's a horse, but then you haven't seen, you know, the rest of the body or something like that. And I find it, I mean, I find it fat, like, I guess there's something about it that, like there might be things that we'd never fully understand here, right? Like we are potentially never going to be able to completely untangle the way that like my cells and my sister cells and the cells from your miscarriages have affected your body. Like it's possible it's always going to remain kind of like a parent-child relationship, right? Like on a tiny scale, there'll be a sort of pushing and pulling and hurting and healing and, you know, a relationship we can explore forever and never fully untangle. To be sure, but to me, the whole benefit of this kind of research is that what you know now, let's say you really, not you, one was really able to go into this, into a lot more depth. There are always surprises. That's the reason everybody does research. They're always like, oh, we were looking for X and we found a whole different section of the alphabet. That strikes me as a good enough reason to pursue it. I'm beginning to realize where I came from. It's beginning to make sense that I have maybe some of your cells in my body and our brain. Question. Would you say I'm overall more of like a scar healing helper or an autoimmune disease trigger of a child? Oh, sweetheart. You are a scar healing helper. It's on the record. I'm so happy you're here. You may be happy you're here, Mama. I love you. I assume that's it. We're done. Yeah, I think that's it. I think we're done. Thank you for doing this. You're very welcome. In a separate space, I will bring you up to date on certain postal events coming your way soon. And you can bring me up to date on another event in your life. This episode was reported and produced by me, Bird Pinkerton. It was edited by Brian Resnick and Catherine Wells, as well as Meredith Hoddinot, who runs the show. We had sound design and mixing from Christian Ayala, music from Noam Hasenfeld, Serena Solin, Tektar Fax, and Manding Nguyen. It's just really lovely to have nearby. I want to say a special thank you this episode to Lee Nelson, who sent so many articles that just really helped orient me and deepen my knowledge here. So if you want to read more about microchimera and autoimmune disorders, look up her body of research. I would also recommend the article that AB Body co-authored in Bio Essays in 2015. If you would like to support the show and the journalism that Vox does, we would love it if you would become a member. It is very easy to do. Just go to vox.com slash members and you will get access to all of Vox's journalism, but you will also know that you are supporting all of Vox's journalism. And for those of you who have emailed to let us know that you signed up because of unexplainable, thank you. And thank you to those of you who have left us a nice review on your podcast platform or told someone in your life about the show. You are all excellent. Unexplainable is part of the Vox Media Podcast Network, and we will be back very soon with another episode about everything that we do not yet know. Thank you.