Omega Therapeutics, Inc | October 14, 2021
Omega Therapeutics, Inc. ("Omega"), a development-stage biotechnology company pioneering the first systematic approach to use mRNA therapeutics as programmable epigenetic medicines by leveraging its OMEGA Epigenomic Programing™ platform, today announced a strategic research collaboration with researchers at the Stanford University School of Medicine to explore the therapeutic potential of Omega Epigenomic Controllers (OECs) to control ocular disease genes associated with inflammation or regeneration of ocular tissues.
Under the terms of the collaboration, Omega and members of the Ophthalmology Department of Stanford University School of Medicine will use the OMEGA Epigenomic Programming platform to discover and research novel ocular targets for potential future OEC development candidates. Albert Wu, M.D., Ph.D., FACS, Associate Professor of Ophthalmology, will serve as principal investigator. Other contributors will include Jeffrey Goldberg, M.D., Ph.D., Professor and Chair of Ophthalmology, and Michael Kapiloff, M.D., Ph.D., Associate Professor (Research) of Ophthalmology.
"Through this research collaboration, we aim to expand the reach of our OMEGA platform within regenerative medicine, immunology, and inflammation with ocular disease targets. We will continue exploration of the broad potential of our disruptive platform and OECs, our new class of mRNA therapeutics as programmable epigenetic medicines."
Mahesh Karande, President and Chief Executive Officer of Omega Therapeutics
About Omega Therapeutics
Omega Therapeutics is a development-stage biotechnology company pioneering the first systematic approach to use mRNA therapeutics as programmable epigenetic medicines by leveraging its OMEGA Epigenomic Programming™ platform. The OMEGA platform harnesses the power of epigenetics, the mechanism that controls gene expression and every aspect of an organism's life from cell genesis, growth and differentiation to cell death. The OMEGA platform enables control of fundamental epigenetic processes to correct the root cause of disease by returning aberrant gene expression to a normal range without altering native nucleic acid sequences. Omega's engineered, modular, and programmable mRNA-encoded epigenetic medicines, Omega Epigenomic Controllers™, target specific intervention points amongst the thousands of mapped and validated novel DNA-sequence-based epigenomic loci to durably tune single or multiple genes to treat and cure disease through Precision Genomic Control™. Omega is currently advancing a broad pipeline of development candidates spanning a range of disease areas, including oncology, regenerative medicine, multigenic diseases including immunology, and select monogenic diseases.
Maravai Lifesciences | August 25, 2020
Maravai LifeSciences, a global provider of life science reagents and services to researchers and biotech innovators, is expanding its contract development and manufacturing organization (CDMO) capabilities at TriLink BioTechnologies for the second time in less than a year. The expansion is expected to be completed in the first quarter of 2021 and will increase TriLink's small molecule manufacturing capacity with a focus on additional scale-up of CleanCap®, its proprietary messenger RNA (mRNA) capping technology, for global mRNA vaccine and therapeutic programs. To further address the increasing demand for mRNA development and clinical programs, the company is currently completing the construction of its plasmid DNA production facility as well. Last November, TriLink opened their new headquarters in San Diego, CA and expanded mRNA and small molecule capacity as it opened five Current Good Manufacturing Practice (cGMP) suites. The current investment will further expand the operation with an additional three cGMP suites and four cGMP manufacturing support suites.
Micreos | September 22, 2020
Dutch biotech company Micreos Human Health has enrolled the first patients in a Phase I/IIa, randomized, double-blind, placebo-controlled, parallel treated dose-ranging study to assess the safety and efficacy of XZ.700 in patients with mild to moderate atopic dermatitis. The study marks the world's first evaluation of a pharmaceutical endolysin for topical use in humans. Endolysins are highly specific enzymes that cut the bacterial cell wall, rapidly killing only the target bacteria, regardless of antibiotic resistance, while preserving the skin microbiome. XZ.700 specifically targets Staphylococcus aureus (S. aureus), a bacterium that is considered to be a causative and aggravating trigger for atopic dermatitis, and viewed as an independent cause of itch, irritation and infection. "The targeted removal of one particular bacterial species, S. aureus, from the skin microbiome, while preserving the beneficial ones is a fundamental new way to treat atopic dermatitis," says dermatologist Dr. Peter Lio, Scientific Advisor for Micreos and Scientific Advisory Board member for the National Eczema Association. XZ.700 is one of several endolysins Micreos has in its portfolio. A structurally similar endolysin, SA.100, is used in the company's over the counter (OTC) products for inflammatory skin disorders (e.g. acne and rosacea), found in the Gladskin range, which have been on the market since 2013. Data obtained in earlier Gladskin studies and feedback from doctors and thousands of customers support the pharmaceutical development program: "I am very encouraged by my experience with Gladskin and I am awaiting the findings with great anticipation." In this study, conducted in The Netherlands, XZ.700 will be tested for its safety as well as pharmacodynamics and efficacy in 48 patients with atopic dermatitis. They will be treated for 14 days with a cream containing XZ.700 at three different concentrations or placebo. Micreos expects to finish the study and report the results towards the end of 2021.