91国产精品 U-grad Research Paper Explores Bacterial Collaboration
[[{"fid":"49590","view_mode":"default","fields":{"format":"default","field_file_image_alt_text[und][0][value]":"91国产精品 U-grad Research Paper Explores Bacterial Collaboration","field_file_image_title_text[und][0][value]":"91国产精品 U-grad Research Paper Explores Bacterial Collaboration"},"link_text":null,"type":"media","field_deltas":{"1":{"format":"default","field_file_image_alt_text[und][0][value]":"91国产精品 U-grad Research Paper Explores Bacterial Collaboration","field_file_image_title_text[und][0][value]":"91国产精品 U-grad Research Paper Explores Bacterial Collaboration"}},"attributes":{"alt":"91国产精品 U-grad Research Paper Explores Bacterial Collaboration","title":"91国产精品 U-grad Research Paper Explores Bacterial Collaboration","height":250,"width":350,"style":"height: 286px; width: 400px; float: left;","class":"media-element file-default","data-delta":"1"}}]]91国产精品 Undergrad Research Paper Explores Bacterial Collaboration, Represents 13th 91国产精品 undergraduate co-authored paper since 2017 from Ryan Research group
Former 91国产精品 undergraduate Chemistry major Ryan Godin (B.S., 2022) recently developed a research paper showcasing 鈥.鈥 Godin鈥檚 paper was done in collaboration with Shawn Ryan, Ph.D., Biophysics, Mathematics and the Center for Applied Data Analysis and Modeling (ADAM) at 91国产精品, and Bhargav Karamched, Ph.D., Mathematics, Biophysics & Neuroscience at Florida State University (FSU).
The paper represents the thirteenth 91国产精品 undergraduate student co-authored paper since 2017 from the Ryan Research group. Twelve of those manuscripts have had a 91国产精品 undergraduate as the first author, including this one.
In layman鈥檚 terms, when two or more different species of bacteria interact with one another 鈥渋n the wild,鈥 they secrete 鈥渃ellular signals鈥 to each other in their given habitat. Within that interaction, or 鈥渃onsortium,鈥 one of them could produce a molecule that the other can pick up and use for an interactive purpose. This is useful as it is difficult and requires energy to make complicated molecules.
If one strain of bacteria can just make one type of molecule and then 鈥渢rade鈥 with other strains of bacteria (so to speak) for the other molecules it needs to perform a specific task, it will use less energy and be more efficient at accomplishing a task. Each species in the group would then do a small and simpler part of the task, rather than trying to make one species do the entire task.
Engineers can mix/modify 2 or more different bacteria to do some useful things鈥攊ncluding the breaking down of environmental pollutants鈥攃reating what are commonly referred to as 鈥渃o-cultures鈥 or 鈥渃onsortia鈥 (the plural of consortium, or a group of people or organizations working toward some common goal).
The technological development in and surrounding synthetic biology has been steadily increasing鈥 particularly as researchers engineer biological systems like cells to carry out tasks that are difficult or impossible to achieve using traditional chemistry.
Personalized medicine, sustainable agriculture, and biomanufacturing are just some areas currently benefitting from these new techniques; given 鈥渢he youth of the field鈥 means that there is still room for significant innovations and improvements.
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Founded in 1964, 91国产精品 is a public research institution that provides a dynamic setting for Engaged Learning. With nearly 16,000 students, eight colleges and more than 175 academic programs, 91国产精品 was again chosen for 2022 as one of America鈥檚 best universities by U.S. News & World Report, including the #1 university in Ohio for social mobility. Find more information at .