Looking Back at an Awesome Fall 2024: A Semester Full of Success and Friendship

Sunghee Lee • December 14, 2024

Can you believe how fast this semester went? The Fall 2024 semester came and went in the blink of an eye, yet we accomplished so much while balancing challenging coursework and engaging research activities. We're really proud of how we keep pushing ourselves to maintain high standards while supporting each other and building a great sense of teamwork. After all, that’s what the Project Symphony is all about.


To close out this amazing semester, we all got together on the last day of classes to celebrate everything we’ve accomplished, both as individuals and as a group. Our gathering was a fun mix of camaraderie and creativity, featuring a coloring session and the gingerbread house competition.


As we reflect on this semester, it’s clear that beyond the data and research papers, we are more than just a group; we are a community. A family bound by intellectual curiosity, mutual respect, and a shared passion for pushing the boundaries of knowledge. Here’s to another semester filled with breakthroughs, support, and the joy of discovery!

Recent Publication: How Tiny Molecules Shape the Flexibility of Cell Membranes

By Sunghee Lee November 15, 2025
Our research team has uncovered new details about how small oil-like molecules influence the thickness and flexibility of cell membranes. These membranes, built from layers of lipids, contain tiny pockets of free space that help control how soft, dense, or permeable the membrane is. Our research team found that some smaller molecules can fit into these layers, making the membrane thicker, while larger or crystallizing ones get pushed out, leading to thinning. These changes help explain how different molecules inside a membrane affect its overall structure and function. This study not only expands our understanding of how biological membranes work but also points to new possibilities for creating custom-designed synthetic membranes for research and technology. Read more details here: https://pubs.acs.org/doi/10.1021/acs.jpcb.5c06296 Congratulations to the Project Symphpony team for their exciting findings and continued dedication to advancing membrane science!

Bacterial Membranes Meet PFAS: New Findings from the Project Symphony Lab

By Sunghee Lee September 2, 2025
We are absolutely thrilled to announce that our Project Symphony, undergrad-fueled research team, just published another article digging into how those stubborn “forever chemicals”, called perfluoroalkyl substances, or PFAS, can mess with model bacterial membranes, making them leakier and less organized than before. It is alarming to discover that these chemicals actively change the physical properties of membranes, and different types of lipids respond in their own way to the disruption, meaning some bacteria could be more affected than others. What makes this work even more special is that our undergraduate team handled every step, and it’s now out there as open access for everyone to read—proof that curiosity and teamwork can lead to great science. The article is appeared in ACS Omega (on August 26, 2025), a publication of American Chemical Society (ACS). Please explore the article here: " Membrane-Modifying Effects of Perfluoroalkyl Substances in Model Bacterial Membranes " https://pubs.acs.org/doi/10.1021/acsomega.5c04177 Congratulations to Micaela, Amani, Jasmin, Jessica, Lizzy, Joey, and Jacqui for their enthusiasm and hard work leading to this contribution! Project Symphony’s journey continues—stay tuned for what’s next.

Celebrating a Remarkable Achievement by Our Undergraduate Research Team!

By Sunghee Lee August 21, 2025
We are incredibly proud to announce that our talented Project Symphony undergraduate research team has just published a significant scientific article in the prestigious Journal of Physical Chemistry B, a leading journal published by the American Chemical Society in physical chemistry research. The newly published study, titled "Biophysical Consequences for Exposure of Model Cell Membranes to Perfluoroalkyl Substances," explores the complex interactions of widely used environmental chemicals (PFAS) with biological model membranes. This research addresses important health and environmental questions, employing various techniques to reveal how molecular structures of PFAS influence membrane properties and permeability. Please read: Biophysical Consequences for Exposure of Model Cell Membranes to Perfluoroalkyl Substances, J. Phys. Chem. B 2025, 129, 31, 7951–7963 https://pubs.acs.org/doi/10.1021/acs.jpcb.5c02472 What makes this achievement truly exceptional is that the work was led and conducted by undergraduate researchers, demonstrating their brilliance and dedication to advancing scientific knowledge. Their contribution not only adds valuable insights into the field of environmental and physical chemistry but also sets an inspiring example of how undergraduate students can make impactful contributions to cutting-edge science. Congratulations to the entire team for this outstanding accomplishment! This publication is a testament to their hard work, curiosity, and the rigorous training they have received.
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