{"id":204911,"date":"2024-10-31T11:16:25","date_gmt":"2024-10-31T15:16:25","guid":{"rendered":"https:\/\/news.syr.edu\/?p=204911"},"modified":"2024-10-31T11:16:54","modified_gmt":"2024-10-31T15:16:54","slug":"future-therapeutic-strategies-may-depend-on-creative-scientific-approaches-today","status":"publish","type":"post","link":"https:\/\/news.syr.edu\/blog\/2024\/10\/31\/future-therapeutic-strategies-may-depend-on-creative-scientific-approaches-today\/","title":{"rendered":"Future Therapeutic Strategies May Depend on Creative Scientific Approaches Today"},"content":{"rendered":"
Before any scientific question can be answered, it must be dreamed up. What happens to cause a healthy cell or tissue to change, for instance, isn\u2019t fully understood. While much is known about chemical exposures that can lead to genetic mutation, damaged DNA, inflammation and even cancer, what has rarely been asked is how physical stressors in the environment can cause a cell or tissue to respond and adapt. It\u2019s a piece of the puzzle upon which future medical breakthroughs might depend.<\/p>\n
Homeostasis refers to a state of equilibrium; at the cellular and tissue level, any changes in environment will spur a response that balances or accommodates it. \u201cMostly people think of chemical changes, exposure to drugs, for instance,\u201d says Schwarz, principal investigator on the project. \u201cHere we ask, what if you squeeze a cell\u2014or a group of cells or tissue\u2014mechanically? Can it still carry out its functions? Maybe not. Maybe it needs to adapt.\u201d<\/p>\n
Alison Patteson<\/a>\u00a0and Jennifer Schwarz<\/a>, both professors in the Department of Physics<\/a>\u00a0and members of the\u00a0BioInspired Institute<\/a>, have been awarded a four-year National Science Foundation grant from Physics of Living Systems, for a project titled “Mechanical Homeostasis\u2014an Emergent Property of the Multi-Tiered Structure of Living Cells and Tissues<\/em><\/a>.”<\/p>\n