A large Mayo Clinic study finds that treating COVID-19 patients with two monoclonal antibodies — casirivimab and imdevimab — can help avoid hospitalization.

New research from the University of Virginia School of Medicine quantifies the antibody response generated by the Pfizer and Moderna COVID vaccines. The findings are some of the earliest to compare the two vaccines’ antibody responses head-to-head. The notable finding was that antibody levels in recipients of the Moderna vaccine were slightly higher than in recipients of Pfizer.

The researchers caution against drawing conclusions about the vaccines’ effectiveness based on the antibody numbers. Both vaccines, they say, have performed exceptionally after having been given to millions of people around the world. The new results are just a small piece in a much larger puzzle as scientists seek to determine if one vaccine may be superior for certain demographics.

“The thing that will be interesting is figuring out if measuring antibody levels ends up being a good marker of vaccine protection,” UVA immunologist Dr. Jeffrey Wilson said. “At the moment, we don’t know for sure.”

The UVA study offers insights into vaccine recipients’ immune response by age.

For the newly reported study, Guilak’s team combined these two strategies to generate a new treatment approach for rheumatoid arthritis.

Researchers at Washington University School of Medicine in St. Louis have used CRISPR-Cas9 genome editing to engineer induced pluripotent stem cells (iPSCs) that can be implanted subcutaneously to deliver an anticytokine biologic drug in response to inflammation caused by rheumatoid arthritis. When implanted into a mouse model of rheumatoid arthritis the engineered cells automatically sensed and responded to inflammatory cytokines, and produce therapeutic levels of the drug, which reduced inflammation and also prevented bone erosion.

“Doctors often treat patients who have rheumatoid arthritis with injections or infusions of anti-inflammatory biologic drugs, but those drugs can cause significant side effects when delivered long enough and at high enough doses to have beneficial effects,” said senior investigator Farshid Guilak, PhD, the Mildred B. Simon Professor of Orthopedic Surgery. “We used CRISPR technology to reprogram the genes in stem cells. Then we created a small cartilage implant by seeding the cells on woven scaffolds, and we placed them under the skin of mice. The approach allows those cells to remain in the body for a long time and secrete a drug whenever there is a flare of inflammation.”

Guilak and colleagues report on their studies in Science Advances, in a paper titled, “A genome-engineered bioartificial implant for autoregulated anticytokine drug delivery.”