In a study published in Nature on Oct. 11, coinciding with the beginning of IDWeek 2023 in Boston, researchers from Harvard Medical School described EVEscape, a method for anticipating the movements of SARS‑CoV‑2 by predicting potential mutations likely to escape current vaccines and treatments.
The vagaries of the COVID-19 market and the uncertainties of pandemic fatigue are hitting some biopharma companies in the pocketbook, at least for now. Due to lower-than-expected revenues from its COVID-19 Comirnaty vaccine and antiviral Paxlovid (nirmatrelvir/ritonavir), Pfizer Inc. reduced its 2023 revenue guidance by $9 billion after hours Oct. 13, saying it now anticipates full-year 2023 revenues to range from $58 billion to $61 billion – down from its previous guidance range of $67 billion to $70 billion.
In a study published in Nature on Oct. 11, coinciding with the beginning of IDWeek 2023 in Boston, researchers from Harvard Medical School described EVEscape, a method for anticipating the movements of SARS‑CoV‑2 by predicting potential mutations likely to escape current vaccines and treatments.
Due to the continual emergence of SARS-CoV-2 mutants, there is an unmet clinical need for broad-spectrum treatments for COVID-19. A potential target for novel treatments is the S2 subunit of the SARS-CoV-2 spike (S) protein, which has been highly conserved across the different variants of the virus.
In a study published in Nature on Oct. 11, coinciding with the beginning of IDWeek 2023 in Boston, researchers from Harvard Medical School described EVEscape, a method for anticipating the movements of SARS‑CoV‑2 by predicting potential mutations likely to escape current vaccines and treatments.
Biopharma happenings, including deals and partnerships, grants, preclinical data and other news in brief: Almirall, Berlin Cures, Biomap, Canariabio, Centrient, Couragen, GPCR, Hikma, Kamada, Ocugen, Pharmenable, Salipro, Sosei, Stem, Theramex, Venatorx, Verge, XNK.
Recently, researchers at Cincinnati Children’s Hospital, in collaboration with colleagues in Japan, have developed a human vascular organoid model that accurately mimics the vascular damage caused by SARS-CoV-2.