CARNEGIE MELLON (US) — Researchers have successfully used simple nuclear magnetic resonance (NMR) to analyze the ‘handedness,’ or chirality, of gold nanoparticles.
The breakthrough could advance the use of the tiny particles in drug development.
The researchers’ approach offers a significant advantage over routine methods for analyzing gold nanoparticles because it can determine whether the nanoparticles exist in a both right-handed and left-handed configuration, a phenomenon called chirality.
Determining a nanoparticle’s chirality is an important step toward developing them as chiral catalysts—tools that are highly sought after by the pharmaceutical industry.
Many drugs on the market today contain at least one molecule that is chiral. Often only one of the configurations, or isomers, is effective in the body. In some cases, the other isomer may even be harmful.
A striking example is the drug thalidomide, which consisted of two isomers: one of which helped pregnant women control nausea while the other caused damage to the developing fetus.
In an effort to create safer, more effective drugs, drug manufacturers are looking for ways to produce purer substances that contain only the left- or right-handed isomer.
Huifeng Qian, a fourth-year graduate student involved in the study, created a gold nanoparticle that has the potential to catalyze chemical reactions that will produce one isomer rather than the other.
The nanoparticle is comprised of precisely 38 gold atoms and measures a mere 1.4 nanometers. Qian worked for nearly a year to grow the nanoparticles into high-quality crystals so that he could study their structure using x-ray crystallography.
“Growing a pure crystal from nanoparticles is very challenging, and you may not even be able to get a crystal at all,” says Rangchao Jin, an assistant professor of chemistry in the university’s Mellon College of Science. “In the nanoparticle community, the crystal structures of only three nanoparticles have been reported.”
In Jin’s case, x-ray crystallography revealed that the gold nanoparticle is chiral. Chemists typically probe the internal chiral structure of gold nanoparticles using a technique called circular dichoism spectroscopy.
When pure chiral molecules are exposed to circularly polarized light, each isomer absorbs the light differently, resulting in a unique—and of opposite sign—spectrum for each isomer. The process of creating the gold nanoparticles, however, often results in a 50/50 mix of each isomer, known as ‘racemates.’
“Because the spectrum is of opposite sign for each isomer, they cancel each other out and the net optical response is zero. This makes circular dichoism (CD) spectroscopy useless when it comes to determining the chirality of gold nanoparticles in 50/50 mixtures,” says Roberto R. Gil, associate research professor of chemistry.
Since Jin couldn’t use circular dichoism spectroscopy, Gil was able to use NMR to help Jin distinguish between his gold nanoparticles’ left- and right-handed isomers.
NMR spectroscopy takes advantage of the physical phenomenon wherein some nuclei wobble and spin like tops, emitting and absorbing a radio frequency signal in a magnetic field. By observing the behavior of these spinning nuclei, scientists can piece together the chemical structure of the compound.
In 1957, scientists observed that the hydrogen atoms of a freely rotating methylene (CH2) group produced two different frequencies if they were close to a chiral center.
Jin’s gold nanoparticles, which have a chiral core, are cushioned by several chemical groups, including freely rotating methylene groups.
Gil reasoned that the nanoparticles’ chiral core should induce the methylene group’s two hydrogen atoms to give off different frequencies, a phenomenon known as diastereotopicity.
Gil and Jin compared the NMR signal from the hydrogen atoms in a non-chiral gold nanoparticle with the NMR signal from the hydrogen atoms in chiral gold nanoparticle.
The non-chiral nanoparticle’s NMR spectrum did not reveal any differences, but the chiral nanoparticle’s NMR spectrum revealed two different hydrogen signals, providing a simple and efficient way of telling whether the particle is chiral or not, even for a 50/50 mixture of isomers.
“NMR is an alternative—and very efficient—method for providing useful information about how the atoms in nanoparticles form the molecular structure.
“Because NMR can determine chirality in some cases, it can readily be used to determine the purity of a nanoparticle mixture,” Jin says.
In current work, Jin and Qian are striving to turn their 50/50 mixture of right- and left-handed isomers into a pure solution of one or the other.
The study was funded by the Air Force Office of Scientific Research and the Camille & Henry Dreyfus Foundation.
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