mRNA Technology Now Used Sucessfully to Treat Heart Disease

Combining technologies that proved hugely successful against cancer and in COVID-19 vaccines, researchers at the University of Pennsylvania have shown they can effectively treat a leading cause of heart disease. For now the success has only been achieved in mice, but the milestone offers hope for millions of people whose heart muscle is damaged by scar tissue. There is no effective treatment for this fibrosis, which leads to heart disease, the leading cause of death in the United States, said Dr. Jonathan Epstein, a Penn professor of cardiovascular research who helped lead the new work, published in the journal Science.

In his new research, Epstein reversed fibrosis by re-engineering cells, as has been done with a successful blood cancer treatment called CAR-T. In this case, however, the treatment took place inside the body rather than in a lab dish. The team delivered the treatment using mRNA technology, which has been proven over the last year with hundreds of millions of people receiving mRNA-based COVID vaccines.

If it works (in people), it really could have enormous impact,” Epstein said. “Almost every type of heart disease is accompanied by fibrosis.”

About 50% of heart failure is directly caused by this scar tissue, which prevents the heart from relaxing and pumping effectively. Fibrosis also is involved in leading causes of lung and kidney disease.

Source: https://eu.usatoday.com

Antibody-Drug Delivery System Kills Cancer Cells With Extreme Precision

It sounds like the stuff of science fiction: a man-made crystal that can be attached to antibodies and then supercharge them with potent drugs or imaging agents that can seek out diseased cells with the highest precision, resulting in fewer adverse effects for the patient.

However, that is precisely what researchers from the Australian Centre for Blood Diseases at Monash University in collaboration with the TU Graz (Austria) have developed: the world’s first metal-organic framework (MOFs) antibody-drug delivery system that has the potential to fast-track potent new therapies for cancer, cardiovascular and autoimmune diseases.

Schematic illustration of the new MOF Antibody crystals and their ability to specifically seek out cancer cells to detect them and deliver highly potent drugs with unprecedented precision

The in vitro study showed that when MOF antibody crystals bind to their target cancer cells and if exposed to the low pH in the cells, they break down, delivering the drugs directly and solely to the desired area.

The metal-organic framework, a mixture of metal (zinc) and carbonate ions, and a small organic molecule (an imidazole, a colourless solid compound that is soluble in water) not only keeps the payload attached to the antibody but can also acts as a reservoir of personalised therapeutics. This is a benefit with the potential to become a new medical tool to target specific diseases with customised drugs and optimised doses.

The findings are now published in the world-leading journal Advanced Materials.

Source: https://www.monash.edu/