Micronized Creatine is essentially creatine monohydrate, but with
much smaller molecules (this creatine has been micronized, which means its molecules have been cut up or divided).
The GI tract is where we break down food into
much smaller molecules, that are then absorbed and used by the body to make energy, repair tissue, and clear toxins.
Fulvic acid is
a much smaller molecule than Humic acid, and it works uniquely in the body.
Not exact matches
Hitherto, in the eyes of a Science too
much accustomed to reconstruct the world on one spatial axis extending in a line from the infinitely
small to the infinitely great, the larger
molecules of organic chemistry, and still more the living cellular composites, have existed without any defined position, like wandering stars, in the general scheme of cosmic elements.
The goat's milk yogurt will not thicken the way cow's milk does, as the fat
molecules are
much smaller, which is why goat's milk does not need to be homogenized, it does not separate the way non-homogenized cow's milk does.
Using computer simulations to predict which drug candidates offer the greatest potential has thus far not been very reliable, because both
small drug - like
molecules and the amino acids of proteins vary so
much in their chemistry.
«
Small molecules are
much easier to make than larger compounds, they are easier to get into cells and their potential for getting into the brain is higher,» he said.
It may also be possible, he adds, «to produce these factors synthetically or develop
small molecules that mimic the activity, but that takes
much longer.»
The
molecule, miR - 34a, belongs to a family of
small molecules called microRNAs (miRNAs) that serve as brakes to help regulate how
much of a protein is made, which in turn, determines how cells respond.
«That's very
much dependent upon the energy of these orbitals and how well they're able to overlap with the orbitals of the
small molecules that are coming to the surface.
«Sodium ions are
much smaller than the hydrogen protons bound to oxygen
molecules in the water in our bodies which are mapped by conventional MRI.
This effect, however, is
small because the wavelength of light is
much longer than the size of a
molecule: the light's corkscrew is too big to sense the
molecule's chiral structure efficiently.
The process allows
small, synthetic
molecules to exhibit the functional diversity of
much larger enzymatic catalysts, and offers a promising new tool for synthesizing therapeutics based on natural products.
Sodium ions naturally occurring in the body are
much smaller than water
molecules and are involved in many body functions associated with pathology.
That, in turn, may render chemical bonds shorter and stronger, making
molecules trapped within such fields as
much as 25 %
smaller, scientists estimate.
Instead of using the chemically linked long - chain
molecules found in traditional rubbers, Ludwik Leibler and his colleagues at the Centre National de la Recherche Scientifique in Paris thought they could make stretchy materials from
much smaller building blocks that associate with each other in a network.
These intermolecular connections, consisting of hydrogen bonds, give the
smaller molecules the stretchiness of
much longer molecular chains.
It contains two essential parts, a
small RNA
molecule called a microRNA (miRNA) which guides RISC to its mRNA target; and a
much larger component into which the guide RNA fits, a protein called Argonaute, which, Joshua - Tor showed in 2004, actually performs the «slicing up» of the mRNA.
«Traditionally, scientists have theorized fairly narrow limits on which proteins can be targeted with
small -
molecule ligands, but our results suggest that those boundaries are
much wider,» said Cravatt.
Rather, the work of folding is done by
much smaller water
molecules, which surround proteins and push and pull at them to make them fold a certain way in fractions of a second, like scores of tiny origami artists folding a giant sheet of paper at blazingly fast speeds.
Saturn's
much smaller moon, Enceladus, features a network of icy volcanoes spewing ammonia, formaldehyde, and other organic
molecules.
With so
much DNA squished into such a
small space, it stands to reason that expressing a gene in the «middle» of the bundle might require loosening the packing material to expose that segment of DNA to the machinery that copies it into an RNA
molecule.
At the moment, I don't think anyone has
much of an idea on how to identify good
small molecule candidates with conventional medicinal chemistry methods (though I'm intrigued to hear that you have some thoughts, AH!).
Individual
molecules and atoms are
much smaller than the wavelengths of light that we can see.
If several thousand new building blocks become commercially available, it may not be too
much of an exaggeration to talk about 3D printing of
small molecules.
Researchers comparing normal and obese mice found that obese mice produced more than twice as
much of a
small microRNA
molecule called microRNA - 143 in their liversANCHOR.
The targets can vary from things that are very
small, like a drug
molecule to something
much larger, like bacteria or viruses.
Hypoallergenic diets contain protein sources that have been broken down (hydrolyzed) into
smaller molecules that are
much less likely to produce an immune reaction than larger intact protein
molecules.
So actually the local radiation field is
much simpler that what you're trying to describe: in the transparent windows, it's just the emitted intensity from the source (sun + ground), and in the opaque lines, it is nearly isotropic with the excitation temperature of the
molecules close to the local kinetic temperature if collisions are numerous enough, with a
small anisotropy linked to the net radiation flux.
The
molecules at TOA have less gravitational energy than
molecules at sea level but not by
much because the change in R is relatively
small.
Due to its
much smaller kinetic diameter, CO2 is preferentially fractionated out of the air pockets when the escape routes have reduced to a size in the lowest levels of the firn that prevents the escape of the larger N2, O2 and CH4
molecules.
Even though the total emissions of these
molecules are quite
small when compared with those of carbon dioxide, they are
much more efficient at trapping infrared heat radiation.
It is the collisions and interactions between multiple
molecules (between the electrons really) that create the
much smaller BB background radiation.
Now the only thing I don't seem to know is the proper division of rates of overall radiation from the bulk atmosphere and how
much might actually reverse thermalize back to the GHG gases with most
molecules just thermalizing again and a
small fraction actually radiating.
While the front part of a dog's nose is almost entirely committed to respiration, the rest is committed to olfaction — the sense of smell — and since there are hundreds of millions more olfactory receptors in a dog's nose compared to a human's nose, a dog is able to smell more and detect a scent in
much smaller quantities: «This means two things: A dog definitely experiences smells, odors — volatile
molecules — that we don't,» Alexandra Horowitz, assistant professor at Barnard College and author of Inside of a Dog, told Modern Farmer.