Lifeboat Foundation

The inside of a mitochondria is made up of a folded membrane, which has evolved to produce the greatest surface area possible between two parts of the mitochondria known as the intermembrane space (the outer part) and the mitochondrial matrix (the inner part). To drastically oversimplify this entire process, the mitochondria uses glucose (and ethanol if it’s available) to pump hydrogen ions (with the occasional deuterium and tritium ion) across the membrane which separates these two compartments of the mitochondria (known as the cristae) into the intermembrane space. These hydrogen ions then flow back into the mitochondrial matrix through a very special protein called ATP synthase, which uses the electrostatic potential energy of the hydrogen ion to manufacture ATP.

Unfortunately, as we get older this inner membrane starts to decay and become smaller. As the cristae starts to shrink, there is less space for ATP synthase, which means there is less ATP produced, which ultimately means that our cells do not have enough energy to maintain all of our cellular functions. As you can imagine, this lack of energy is catastrophic for the health of the cell, and will eventually lead to either cell senescent (where the cell essentially becomes dormant), or complete cell death.

Numerous different suggestions have been put forward as to explain why exactly why mitochondria decay in this way, including mutations within the DNA of the mitochondria (they have their own chromosomes), as well as the build up of oxidative agents within the cell itself which cause direct damage to the mitochondria. However, a group of scientists lead by Dr Hazel Szeto have discovered that the decay of the mitochondrial cristae is linked to declining levels of a phospholipid (fat) called cardiolipin. It turns out that as we age, oxidative agents within our body destroy this phospholipid, which is essential for maintaining the folded inner membrane of the mitochondria.

In some products it is not listed as an ingredient.

More than half the cosmetics sold in the United States and Canada likely contain high levels of a toxic industrial compound linked to serious health conditions, including cancer and reduced birth weight, according to a new study.

Summary: A new imaging study reveals how the MFSD2A transporter protein provides a gateway for omega-3 fatty acids to enter the brain.

Source: Columbia University.

Spectacular images of a molecule that shuttles omega-3 fatty acids into the brain may open a doorway for delivering neurological therapeutics to the brain.

Nanoengineers at the University of California San Diego have developed immune cell-mimicking nanoparticles that target inflammation in the lungs and deliver drugs directly where they’re needed. As a proof of concept, the researchers filled the nanoparticles with the drug dexamethasone and administered them to mice with inflamed lung tissue. Inflammation was completely treated in mice given the nanoparticles, at a drug concentration where standard delivery methods did not have any efficacy.

The researchers reported their findings in Science Advances on June 16.

What’s special about these nanoparticles is that they are coated in a cell membrane that’s been genetically engineered to look for and bind to inflamed lung cells. They are the latest in the line of so-called cell membrane-coated nanoparticles that have been developed by the lab of UC San Diego nanoengineering professor Liangfang Zhang. His lab has previously used cell membrane-coated nanoparticles to absorb toxins produced by MRSA; treat sepsis; and train the immune system to fight cancer. But while these previous cell membranes were naturally derived from the body’s cells, the cell membranes used to coat this dexamethasone-filled nanoparticle were not.

Check out my short video in which I explain some super exciting research in the area of nanotechnology: de novo protein lattices! I specifically discuss a journal article by Ben-Sasson et al. titled “Design of biologically active binary protein 2D materials”.

Here, I explain an exciting nanotechnology paper “Design of biologically active binary protein 2D materials” (https://doi.org/10.1038/s41586-020-03120-8).

Continue reading “Synthetic protein lattices explained” »

Circa 2015

Coatings that attract water (hydrophilic) are useful for anti-fogging applications⁶; any liquid water spreads out into a thin film thereby maintaining transparency. This is more favorable than using hydrophobic surfaces for anti-fogging as this requires a surface to be tilted for the droplets to roll off and transparency be maintained. Hydrophilic surfaces can also be used for self-cleaning⁷. Previous examples of superhydrophilic surfaces include the use of polymer–nanoparticle coatings^8,9,10,11 however mechanical durability was not investigated.

Coatings with surface tensions lower than that of water (72 mN m^–1) but higher than that of oils¹² (20–30 mN m^–1) will attract oils (oleophilic) but repel water and can be used to create oil–water separators^13,14,15. When applied to a porous substrate, the coating will allow the passage of oil but block the passage of water, resulting in their separation. In addition, their water repellency also makes them ideal for self-cleaning^4,16 and anti-icing^17,18,19 applications. Anti-icing surfaces are typically superhydrophobic as supercooled droplets of water are able to roll off the cold surface before freezing and any ice formed is weakly adhered compared to hydrophilic surfaces due to an air cushion^18,20.

Continue reading “Bioinspired, roughness-induced, water and oil super-philic and super-phobic coatings prepared” »

Brain on a chip employs microfluidic technology for studying the brain and its associated diseases in vitro. uFluidix article.

Circa 2020

Researchers at UC Berkeley have developed a rapid test for SARS-CoV-2 that uses an enzyme to cleave viral RNA, initiating a fluorescent signal that can be detected using a smartphone camera, and which can provide a quantitative measurement of the level of viral particles in the sample. The test produce a result in as little as 30 minutes and does not require bulky or expensive laboratory equipment.

Continue reading “CRISPR Test Uses Cell Phone Camera to Detect SARS-CoV-2” »

A ball of 4000-year-old hair frozen in time tangled around a whalebone comb led to the first ever reconstruction of an ancient human genome just over a decade ago.