> I think it would be better to describe this as an ‘organelle’ transplant as it would be easier for people to understand and discuss.
Unlike previous attempts, the donor mitochondria are not transferred into the mother egg. Instead the donor cell is denucleated, and the nucleus from a mother's egg is transferred into the denucleated donor cell. Consequently, there is a wide variety of donor specific material, which may influence the early stages of development and only "wash out" after a number of cell divisions.
> But calling it a 3 person baby is unhelpful and misleading as IMO mitochondria DNA is of a different category to chromosomal DNA.
How so? Arguably, mitochondrial genes are much more essential than most nuclear genes.
1. Mutations in any mitochondrial gene often have dire consequences, whereas variants in nuclear genes are much more frequent.
2. Mitochondrial DNA is the most expressed in pretty much any cell by a huge margin. Mitochondria express 13 (IIRC) protein coding genes and two dozen other RNAs. Those 30 odd genes often make up 1-5 % of a cell's whole transcriptome. Only genes coding for ribosomal RNA are more strongly expressed.
You finish your degree, and start your PhD. The first year, you are busy learning techniques and getting caught up with the relevant literature.
You are far too concentrated on learning new things to get any thinking done.
In your second year of your PhD, you are getting better. You can do most things without thinking about them. This frees up your brain to think about other things.
However, your grasp of the wider literature is still lacking, so you use that brainspace to optimise your current experiments (as you should).
In your third year of your PhD, you are starting to write things up: either your thesis, or your first (big) paper. You read a lot more, you know a lot more.
The deep thinking can commence.
Your first postdoc is probably your most productive time: you know what you are doing; you know the state of the literature and which parts are reliable and which aren't; you have a clear idea of what problems need solving.
You are starting to write your first grant applications, but you only need one for yourself and not several to cover the needs of a full lab. You don't have any kids at home.
This is a good time to solve some big problems. It lasts about 2-3 years.
At the start of your second postdoc, you panic. The big problem was harder than you thought and you don't have enough high-impact papers to be competitive in job applications for a principal investigator (PI) role.
You start churning out low-value fillers and collaborating with everyone and their hamster to get your name on as many papers as possible.
The rest of the time is taken up by applying for grants and PI positions. You don't even make it to the interview stage. You start pondering about life outside of academia.
Huge fan of Distill here (and your personal blog).
> In retrospect, I deeply regret trying to run Distill with the expectations of a scientific journal, rather than the freedom of a blog, or wish I'd pushed back more on process. Not only did it occupy enormous amounts of time and energy, but it was just very de-energizing.
Scientific peer review pretty much always is incredibly draining, and (assuming the initial draft is worth publishing) it rarely adds more than a few percent to the quality of the article. However, newcomers are drowning in a sea of low quality SEO spam (if they bother to search & read blogs at all and don't go straight to their LLMs, which tend to regurgitate the same rubbish). The insistence on scientific peer review created a brand, which to this day allows me to blindly recommend Distill articles to people that I am training or teaching. So I, for one, am incredibly grateful that you went the extra-mile(s).
The range notation indicates 95% confidence intervals, not the minima and maxima. If the lower bounds are close enough to zero (and the interval is large enough), then there may some residual probability mass associated with negative values of the variable.
I am a biochemist and neuroscientist and also thought it was fantastic read. It's rare that someone manages to cater to both audiences this well. Kudos!
Some animals get most if not all of their sleep through microsleep [1].
So whatever mechanism "refreshes" the brain, it can work on short time scales.
The switch in brain firing dynamics from wake to sleep (NREM) is very fast -- on the order of one to a few seconds. People in team Nedergaard argue that it is the rhythmic neuronal activity during sleep that promotes fluid flow (though to be fair, some argue its arterial pressure). So their answer to your question would be yes, that should be enough time to enhance fluid flow (fluid is flowing all the time, the question debated by scientists is, whether is it being enhanced during sleep).
I don't think that translates to humans. Sleep disturbances like the micro-arousals triggered by sleep apnea absolutely ruin lives, way before lack od oxygen becomes a problem. Arousals destroy sleep architecture. Humans cannot thrive on microsleep.
I wonder how much of an effect physical brain size has on this. Square-cube law and all that. Bird brains are famously small (though highly efficient).
It is worth noting that these topical applications are quite controversial in the medical literature. The evidence supporting a dermal absorption of magnesium (or other electrolytes) is pretty poor [1]. In that sense: yes, it would be exceedingly difficult to overdose using them.
Underresearched topic for sure. They do cite studies that show some effects, just not convincing enough. Perhaps the weak effects are because they seem to overindex on serum magnesium levels, which is just not a good marker of magnesium status (unless very deficient). It's largely an intracellular/skeletal element and serum levels are quickly maintained by kidneys within a narrow range. Magnesium RBC is a much better biomarker but it's hard to find any studies that focus on it. Here's one but in a non-mainstream journal:
https://ijlbpr.com/uploadfiles/462vol12issue2pp2557-2563.202...
Anectodally, while on B6, I had a period of magnesium intolerance - it was a reliable trigger for my dysautonomia flares. I did have reactions to magnesium chloride spray - tachycardia, blood pressure spike, sometimes headache within ~15 minutes of applying it.
There's an awful lot of personal susceptibility linked to the use of magnesium I suspect. In other words what's good for one person may not be good for another. For me magnesium in chloride hexahydrate form converted into a magnesium oil spray is great for a lot of things like aches and pains, and even improving sleep patterns. It's also dirt cheap if you make it yourself. Also magnesium citrate is perfect for me to regularize bowel movements. But again, YMMV.
human nuclear genome size (haploid): 3.1 billion bp
mitochondrial genome size: 16 000 bp
1 human nuclear genome per egg -> 3.1 billion bp nuclear DNA
100 000 mitochondria, each with 1-10 genomes per mitochondrion [1] -> 1.6-16 billion bp mitochondrial DNA
So the ratio of mitochondrial to nuclear DNA in human eggs is on the order of 0.5 to 5.
[1] https://pmc.ncbi.nlm.nih.gov/articles/PMC4988970/