Tag: Organic Chemistry

Scientists at Nanyang Technological University, Singapore (NTU Singapore) have developed a technique to observe how radiation damages molecules over time-frames of just one quadrillionth of a second — or a femtosecond. The technique involves dissolving organic molecules in water to simulate the state molecules are found in biological tissue. This allows the research team to

Prozac®, the trade name for the drug fluoxetine, was introduced to the U.S. market for the treatment of depression in 1988. Thirty years later, scientists still don’t know exactly how the medication exerts its mood-lifting effects. Now, researchers report that, in addition to the drug’s known action on serotonin receptors, fluoxetine could rearrange nerve fibers

Cells are incredibly adept at creating complex molecules, like therapeutics, and can do so much better than many of our best factories. Synthetic biologists look to re-engineer cells to make these molecules for specific needs, including pharmaceuticals and energy applications. But the trial-and-error process is difficult and time-consuming, and often competes with the cell’s other

A team of researchers from New York University has engineered nanoscale protein micelles capable of both delivering chemotherapeutic drugs and of being tracked by magnetic resonance imaging (MRI). The innovation falls into the category of “theranostics,” meaning that it combines diagnostic capability and drug delivery, allowing researchers to administer therapy while also non-invasively monitoring the

Researchers from North Carolina State University have created the largest publicly available virtual library of macrolide scaffolds. The library — called V1M — contains chemical structures and computed properties for 1 million macrolide scaffolds with potential for use as antibiotics or cancer drugs. “As chemists, we’re only able to look at a tiny portion of

Protein nanopores are present in cell membranes and act as biological gateways. This means that they can also be used for the detection of specific bioactive molecular chains, like sugar chains, such as molecules from the glycosaminoglycan family. The latter are responsible for key interactions at the cellular level. They typically mediate interactions with cell

Cancer researchers struggle to identify tumor cells that are interspersed within nonmalignant tissues because tumor cells exploit the tissue environment and monopolize available resources to continue growing. Researchers attribute cancer cell’s ability to use cell signaling and metabolic pathways that override normal cell growth restrictions to complicated chemical exchanges between tissue and tumor cells. A

Decades after scientists discovered hundreds of different fatty acids in vegetable oils, two that had managed to elude detection have finally revealed themselves to a team led by the University of Nebraska-Lincoln and Huazhong Agricultural University in China. Named for the sites of the two leading institutions, Nebraskanic acid and Wuhanic acid make up nearly

Invented over 50 years ago, flow cytometry-based cell sorting has become a widely used tool in biology labs for physically isolating cells based on their global surface marker expression profiles. But on August 27 in the journal Cell, an international, multi-institutional team of researchers unveil the next evolution in this critical process, “Image-Activated Cell Sorting,”

A new combination of existing drugs shows promise that it could reduce the size of cancerous tumors much more effectively than current treatments. As cancer patients know all too well, many highly effective anti-cancer drugs don’t stay effective long. Most tumors will become drug resistant over time as their cells rapidly mutate. Chemists from The

When it comes to certain molecules, shape makes all the difference. The shape of limonene, for instance, a compound produced by citrus fruits, determines whether it tastes like orange juice or turpentine. In the case of therapeutics, the 3D shape of a molecule can be critical to activity. Now, scientists at Scripps Research and Bristol-Myers

How do complex biological structures — an eye, a hand, a brain — emerge from a single fertilized egg? This is the fundamental question of developmental biology, and a mystery still being grappled with by scientists who hope to one day apply the same principles to heal damaged tissues or regrow ailing organs. Now, in

Human cells are enclosed by membranes and are in osmotic equilibrium with their environment. If the concentration of solute molecules (osmolarity) in the fluid surrounding the cells decreases, cells start to swell; in extreme cases, this can result in the cells bursting. To avoid this, cells activate volume-regulated chloride channels (VRACs) of the LRRC8 protein

Kyoto University scientists are one step closer to designing porous materials that can change and retain their shapes — a function known as shape-memory effect. Shape-memory materials have applications in many fields. For example, they could be implanted in the body and then induced to change shape for a specific function, such as serving as

Biomedical engineers at Duke University have used a CRISPR/Cas9 genetic engineering technique to turn off a gene that regulates cholesterol levels in adult mice, leading to reduced blood cholesterol levels and gene repression lasting for six months after a single treatment. This marks the first time researchers have delivered CRISPR/Cas9 repressors for targeted therapeutic gene

A team of researchers led by Dr. Mike Sleutel from the VIB-VUB Center for Structural Biology in collaboration with scientists from the Institute for Complex Molecular Systems of the Eindhoven University of Technology, and the CNRS in Grenoble, have for the first time uncovered the molecular details of protein crystal nucleation, a process with great