As reported in a previous post, innovations in image capture and post-image processing have led to significant gains in resolving power.
This overall trend continues with two new exciting developments in the field. The advancements reported below push the limits of resolution even further than before, enabling our ability to view single-molecule interactions and single cell activities in live cells with unprecedented detail.
Previously, even the highest resolution microscopy techniques could only image structural details of proteins and nucleic acids at levels above nanometer scale. This precluded the ability to map conformational information critical to how these biomolecules interact, signal, and carry out their duties. High resolution structural studies remained in the domain of solid-state techniques, like X-ray crystallography and Cryo-EM, and the large-scale averaging of data involved in these methods.
Atomic Force Microscopy (AFM) is a technique that employs a mechanical probe to scan the surface of biological specimens or materials. AFM's tiny but accurate and precise movements can reveal fine details of surface topology at sub-nanometer scales. This technique can achieve atomic resolution of solid surfaces, silicates, semiconductors, etc. However, it cannot achieve this level of resolution for biomolecules in solution or under physiological conditions.
The authors of a recent study published in Nature borrow a concept from modern optical microscopy to bring higher resolution to AFM imaging. In super-resolution optical microscopy, two fluorescent probes in a sample in very close proximity are visualized with the help of advanced computational algorithms. This in turn permits reconstruction of miniscule measurements between these probes. The investigators of the new technique, termed “Localization Atomic Force Microscopy” (LAFM), harness attributes of both optical and AFM techniques.
As opposed to solid state structural techniques such as X-ray crystallography, which average data from many molecules, the new LAFM technique permits capture of multiple images of single molecules. This provides imaging of atomic level resolution of single molecules in solution and under biological conditions.
A second recent development focuses on the major issue of resolving single cells using optical microscopy, and specifically the extreme intensity of the light that is required. Microscopes that are used to examine the details of biological systems employ one or two intense light sources. The more powerful the light from these microscopes, the greater the biological detail. However, this comes at the expense of potentially harming or destroying the living specimen.
The authors of a new study published in Nature use a quantum trick to squeeze or condition the light from the photon source. By sending the light beam through a special crystal, only paired photons (quantum pairing) with similar energies are focused on the sample. Removing excess light and noise through this method results in lower intensities and subsequently less damage to biological samples.
The implication of this new technique includes: greater diagnostic power in determining cancerous from benign cells, better understanding of cell-to-cell communications, greater ability to visualize live-cell events such as gene expression and apoptosis, and many other applications.
The advancements described above serve to once again push the resolution barrier, enabling new insights at the atomic level, within single cells, and in the context of living biological processes. Pretty amazing stuff with more that’s sure to come in this intense and innovative field.
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