Chicken feathers can be used to reduce hair loss and nausea from chemotherapy - study
The team members said their development will make it possible, for the first time, for faulty enzymes to be replaced within the body.
Chemistry experts at the famed Kings College London and the Francis Crick Institute have developed a new drug-deliver technique using proline, an amino acid found in chicken feathers and skin tissue that could be utilized to minimize the side effects of chemotherapy and repair important enzymes.
Just published in the journal Chem under the title “Metal-Peptidic Cages – Helical Oligoprolines Generate Highly Anisotropic Nanospaces with Emergent Isomer Control,” the study explains how Dr. Charlie McTernan and colleagues have created a cage (a box made of single molecules) from biologically compatible peptides, which are short amino acids that form the basis of proteins. These cages can house drugs of different sizes and transport them in the body with high levels of precision.
The negative side effects associated with chemotherapy, such nerve damage and the loss of hair caused by toxicity in which the treatment kills healthy, rapidly dividing cells surrounding tumors and the tumor itself. By creating a nano-sized cage to house the drug and carry it into the malignancy before releasing it, this effect can be targeted directly at the tumor, protecting healthy cells.
Proline is very rigid and straight in shape, while also being soluble in water, which makes it uniquely suited for drug delivery, since water makes up more than half of the human body. By binding the peptide to small amounts of metal such as palladium, the researchers could create a structure they could rapidly increase or decrease in size.
As proline and collagen are widely available and don’t rely on chains of hydrocarbons like previous methods, the team hope to sustainably scale up their current production in the lab.
Increasingly complex architectures
Advances in self-assembly have enabled the construction of increasingly complex architectures from simple building blocks. The self-assembly of metal-organic cages enables the rapid creation of atomically defined, three-dimensional, nanoscale forms that are like proteins, but existing metal-organic cages are almost always built from rigid and flat panels.
Recent work has focused on the construction of simple metal-organic polyhedra – that have a 3-D shape with flat polygonal faces, sharp corners, and straight edges – thanks to their reliable and predictable assembly from rigid, flat, systems.
The cage can be created in a variety of sizes, making possible different drug payloads. This flexible structure allows for chemotherapy drugs, antibiotics, and antivirals to be delivered to the malignancy site. Until now, cages of this kind could be made only by using hydrocarbon molecules found in tar that is often toxic to people.
The team members said their development will make it possible, for the first time, for faulty enzymes to be replaced within the body. The activities of enzymes, which are made up of proteins and carry out vital bodily functions, could have been blocked only by drugs. But the new discovery could have an impact in the body by reducing inflammation; the cages could replace this function which may lay the groundwork for a new form of treatment.
“We’ve created is essentially a biologically compatible molecular teabag,” McTernan explained. “We can fill this teabag – the cage made from widely available proline and collagen –with several different medicines and deliver them in a much more targeted way than we could before. In time, we hope that this could limit hair loss, nausea, and other unpleasant side effects of chemotherapy. We might even be able to repair malfunctioning enzymes that have an influence on the development of cancer.”
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