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Registration is now available for the 13th International Conference on Biomolecular Engineering (ICBE25)! Attend the premier conference that brings together researchers who are using quantitative approaches to advance the understanding and application of molecular biology. Funding is available to help sponsor registration costs. Students/post-docs and early-career professionals are encouraged to apply! Early bird rates are in effect through November 15, 2024: https://lnkd.in/dCwDveAm Apply For Funding: https://lnkd.in/ePPPwegA Keynote Speakers: April Kloxin, Professor, University of Delaware Danielle Tullman-Ercek, Professor, Northwestern University Jonathan Silberg, Professor, Rice University Conference Topics: Biomaterials and Engineered Living Materials Biomolecular Engineering for Human Health Biomolecular Engineering to Advance Fundamental Science Cellular and Tissue Engineering Emerging Technologies in Molecular Engineering Metabolic Engineering Nucleic Acid Engineering Plant and Environmental Engineering Protein Engineering Conference Chairs: Gözde S. Demirer, Caltech Kevin Solomon, University of Delaware Organizing Committee: Aditya Kunjapur, University of Delaware Chelsea Y. Hu, Texas A&M University Jonathan Conway, Princeton University Katie Galloway, MIT Lydia Contreras, University of Texas, Austin Michael Smanski, University of Minnesota Quinton Smith, University of California, Irvine #ICBE #ICBE25 #MolecularBiology #Molecular #Biology

Breaking News: A facile approach for growing Ag nano-dendrites employing towards E. coli cells monitoring using SERS: a proof-of-concept study. We've made a breakthrough in Research! Our team has developed a simple and efficient method to grow silver nanodendrites, which have incredible potential for sensitive and E. coli cells monitoring using SERS. In our proof-of-concept study, we successfully used these Ag nanodendrites for surface-enhanced Raman spectroscopy (SERS) to monitor E. coli cells. #nanotechnology #silver #nanodendrites# #SERS #bacteria #E.coli #science #research #innovation# To learn more about our groundbreaking research, check out our paper: [DOI 10.1088/2632-959X/ad8466]. Thank you for your invaluable guidance and support"[Dr.Anand Sir,Dr.Shailen Sir and Dr.Tulika Mam] "I'm grateful for the collaboration and teamwork."[Aarti,Abhishek and Akila] "I couldn't have done it without your love and support."[Mom and Dad]. Call to action: Join the conversation! Share your thoughts on this exciting development and its potential applications.

Catch the wisdom of Prof. Dr. Sir Richard J. Roberts, Nobel Laureate and Chief Scientific Officer at New England Biolabs. In his interview, he shares his insights on #science, tackling #research challenges, and the importance of #OpenAccess. Interesting fact: Prof. Roberts initially considered a career as a detective before discovering his passion for chemistry and molecular biology! Watch the full interview here to hear more about his fascinating journey and perspectives: bit.ly/3z9pB3M #RisingStars

We are honored to introduce Prof. Emmanuel MARGEAT as an invited speaker at this year's Single Molecule Workshop. Prof. Margeat will talk about "Dissecting the structural dynamics of a GPCR using smFRET". He is Director of the Centre de Biologie Structurale, Montpellier, France. His lab advances single molecule biophysical methods and applies them to the study of macromolecular complexes at biological membranes. These are involved in membrane organization and remodeling, mechanical transduction and chemical signal transduction. Don't miss the opportunity to learn from him, ask your questions, and discuss your research challenges! October 8 - 10, 2024 Berlin, Germany ➡️Present your own results and submit your abstract by July 24: https://lnkd.in/dpXy-4A ➡️Register by September 6: https://lnkd.in/dpXy-4A #smFRET #molecules #spectroscopy #microscopy #fluorescence #materialsscience #lifescience

Check out our submission for the #spotlightprize organized by Jong KNCV | Young Royal Netherlands Chemical Society ! In a 1 minute video we explain our work on deforming artificial cellular membranes on demand using synthetic molecular motors. In nature, mechanical forces exerted by the cytoskeleton or proteinaceous coats are responsible for introducing membrane curvature and deformations, of most importance in crucial cellular processes such as differentiation, trafficking, and division. In our work, we introduce an innovative approach to induce curvature effects by integrating a rotary synthetic molecular motor into phospholipid membranes. These molecular machines have the ability to induce sustained disequilibrium when exposing the system to visible light, thereby enabling on-demand deformations of the membranes. Overall, our research contributes to a comprehensive understanding of how molecular motors interact with lipid membranes, elucidating the multifaceted factors that govern membrane responses together with significant advancement in comprehending and harnessing the potential of such molecules in biological contexts. Many thanks to Yusuf Qutbuddin for helping creating this beautiful movie and the Feringa and Schwille labs for the research opportunity. #spotlightprijs #spotlightprize #chemistry #molecularmotors #membranebiophysics #phd

🔍 Curious about our facilities? Take a peek into our single-cell unit! Vinayaka H. Damle, our optical researcher, shared some exciting updates on the capabilities of our single-cell unit. Currently, we can optically trap microbial cells in microfluidic environments and manually sort them based on physical properties, such as shape, size, or fluorescence. But soon, with our fully functional single-cell unit, the possibilities are endless: 1️⃣ Cellular phenotyping using Raman-activated cell sorting. 2️⃣ Exploring ecological pathways and metabolisms. 3️⃣ Investigating cell chemistry in situ with Raman micro-spectroscopy. 4️⃣ Detect labeled cells within microbial communities using Raman spectra, sorting metabolically active cells for downstream analysis. Stay tuned for groundbreaking discoveries in microbial research! #UNLOCKMicrobialPotential #singlecellunit #UNLOCKInnovation 🌱🔬

The journal 'Analytical and Bioanalytical Chemistry' has just published a Topical Collection on Luminescent Nanomaterials for Biosensing and Bioimaging. It has been guest edited by Li Shang from Northwestern Polytechnical University, Chih-Ching Huang from National Taiwan Ocean University and Kaohsiung Medical University, and Xavier Le Guevel from Université Grenoble Alpes, who invited several authors to highlight recent advances in developing various luminescent NPs for biosensing and bioimaging applications. Take a look at all contributions that include trends articles, papers in forefront, critical reviews, and reserach papers: https://lnkd.in/eG269Dqt #luminescence #nanomaterials #biosensors #analytical #bioanalytical #chemistry #analyticalchemistry #topicalcollection #specialissue #springer #springernature #springerchemistry Springer Nature Group Springer-Verlag | Part of Springer Nature

The conventional view of how living cells are organized has changed dramatically over the past decade. Clifford Brangwynne, the June K. Wu ’92 Professor of Chemical and Biological Engineering, has played a starring role in that revolution. Starting with a 2009 paper, his research began fusing molecular biology and materials science, leading to foundational insights about the physics of tiny cellular compartments known as organelles and suggesting new ways to treat diseases such as cancer, ALS, and Alzheimer’s. Before that breakthrough, scientists viewed organelles like soap bubbles, with a distinct membrane separating inside from out. Brangwynne and his then-adviser Anthony Hyman showed that many structures within cells are more like raindrops, where bio-molecules condense from their surroundings and band together — no membranes, no skins. At first, the finding made only a quiet impression on the scientific world. When Brangwynne joined the Princeton chemical and biological engineering faculty in 2011, the paper had garnered fewer than 10 citations. But he and his colleagues have since produced a steady flow of research that extends the original finding and demonstrates far-reaching implications for cell biology, bioengineering, and biomedicine. A community of scientists took note and began to contribute to the growing field. Today, a search for “biomolecular condensates” or “membraneless organelles,” as these compartments are called, returns more than 40,000 research results in Google Scholar. Read more: https://lnkd.in/enVkS8pf

Registration is now available for the 13th International Conference on Biomolecular Engineering (ICBE25)! Attend the premier conference that brings together researchers who are using quantitative approaches to advance the understanding and application of molecular biology. Funding is available to help sponsor registration costs. Students/post-docs and early-career professionals are encouraged to apply! Early bird rates are in effect through November 15, 2024: https://lnkd.in/dCwDveAm Apply For Funding: https://lnkd.in/ePPPwegA Keynote Speakers: April Kloxin, Professor, University of Delaware Danielle Tullman-Ercek, Professor, Northwestern University Jonathan Silberg, Professor, Rice University Conference Topics: Biomaterials and Engineered Living Materials Biomolecular Engineering for Human Health Biomolecular Engineering to Advance Fundamental Science Cellular and Tissue Engineering Emerging Technologies in Molecular Engineering Metabolic Engineering Nucleic Acid Engineering Plant and Environmental Engineering Protein Engineering Conference Chairs: Gözde S. Demirer, Caltech Kevin Solomon, University of Delaware Organizing Committee: Aditya Kunjapur, University of Delaware Chelsea Y. Hu, Texas A&M University Jonathan Conway, Princeton University Katie Galloway, MIT Lydia Contreras, University of Texas, Austin Michael Smanski, University of Minnesota Quinton Smith, University of California, Irvine #ICBE #ICBE25 #MolecularBiology #Molecular #Biology

Come to see how as little as 2 microliter of charge variant collected from icIEF-based fractionation with MauriceFlex can be used for SPR binding assay.