July 22, 2016, Filed Under: 2016, cancer, researchResearch Updates! It is crazy to think we are on week 7 out of our 10 weeks here at the UT Austin BME department! Research is a notoriously slow process, but many of us REU students are finally starting to get some meaningful data. Across the board, all of us have vastly improved our skills and knowledge in the lab and are enjoying are heightened independence within our individual projects. Now faced with the daunting task of reporting our results in an abstract and poster, we are all beginning to consolidate our work and practice those scientific communication skills we have been working on! 🙂 The REU students report their research progress and accomplishments so far: Alston: I have seeded fibroblast cells and invasive breast cancer 231s cells onto my electrospun aligned and nonaligned fibers. I’m doing data analysis on the fibroblast cells to see the rate they proliferated. Adiel: I have been examining the effects that stiffening has on macrophages in order to better understand how macrophages behave within the tumor microenvironment. This is being done by placing macrophages into alginate gels of different degrees of stiffness, and examining their behavior. Hannah:  I’ve been developing a new MATLAB algorithm to quantify inward movement and hopefully endocytosis. Right now we’re applying it to a cell line that’s drug resistant and treated with a certain kind of inhibitor, and we’re trying to test if the treated cells will show less inward movement in the trajectories we collect. Dylan: I am developing a low-cost imaging system primarily using 3D printed parts. This system will utilize the Laser Speckle Contrast Imaging (LSCI) technique to track relative blood flow in the brain. This technique is used by physicians and researchers to observe how blood flow returns to damaged parts of the brain after the removal of tumors. Nyrobi’s phantom gels Emilio’s smart glasses Dylan’s early model Adiel’s macrophage gels Rachel: I have been exploring how the changes in the stiffness of the microenvironment of breast cancer cells affects the cancer cells resistance to doxorubicin. So far this summer, I have seeded 3 experiments of the hydrogel based cell cultures in which I varied the dosages, acclimation times, and stiffness of the gels. Currently, I am performing Live/Dead assays to quantify the cancer cells response to doxorubucin. Grant: I’ve been working on creating liposomal nanoparticles to create a better binding site between the two membranes that fuses them together. We achieve this fusion by mixing the lipids that make up the membrane with this one specific lipid called DOTAP which due to its charge is attracted to the cell membrane and causes the fusion. Over my experiments so far in the lab, our results have found that lipids composed of 8% DOTAP deliver the best out of any variety of concentrations. We were able to determine this by dying one of the lipids and then scanning the cells and seeing how many cells were determined to fluoresce. Nyrobi: I am creating a tissue phantom to see how light can be manipulated in order to detect cancer noninvasively. I am using an imaging technique that is sensitive to scattering and absorption, and will allow us to accurately identify the boundaries of tumors. The first seven phantoms I made had bubbles that were too close to the phantom holes where the fluorescent dye will be. The last phantom made had very few, very small bubbles not close to the holes that would affect the results. Currently I’m making a new phantom with less scattering components in order to possibly see the fluorescent dye easier in the shorter phantom holes. Daniel: I am working on how physical environment forces such as strain (stretch) affects the behavior of cancer cells. So far we have seen mix results, with some knockout and knockdown cancer cell lines exhibit more cell adhesion while others resemble more metastatic behavior. Sydney: I compiled data about the interaction of PO4, cAMP and cGMP with different proteins then used that data to determine their most common interacting residues and atoms. I am using that data to isolate ligand residue interactions via Pymol then am running energy decomposition analysis to quantify the dominate forces in the interaction. Compiled by Sydney Hutton, Stanford
July 12, 2016, Filed Under: 2016, cancer, texas4000Letter to Texas4000 Rider: Matthew Schneider Dear Matthew, Hey Matthew, my name is Dylan Beam and I just finished my first year studying Biological Engineering at The Ohio State University. I am in complete awe of what you guys are all accomplishing this summer. I am from Oregon, so I fly about 2500 miles pretty regularly to and from college and I couldn’t imagine riding a bike that far, much less the 4000 miles that you are all biking this summer. Everyone’s life has been touched by cancer at one point or another–mine was touched when a close family friend was diagnosed with breast cancer–but I could not imagine what it is like to have one of my parents afflicted by this horrific ailment. It’s inspiring to me that you have taken on the journey to raise funds and awareness for cancer by participating in Texas 4000. Dylan, 2016 Summer Scholar I have been interested in research because of the intellectual stimulation it provides, but through this connection to Texas 4000 I have gained better insight on the impact that research can have on individuals. I remember back to how when I was a kid and everyone wanted to be a hero. This program has helped me to understand that heroes come in all types. You are a hero, just like every other member of Texas 4000 and everyone else dedicating their life to fighting cancer. I’ve lived my whole life on the west coast between visiting my family in the San Francisco Bay Area and living in Oregon. It’s a beautiful area and I hope you enjoy your journey through the west. Sincerely, Dylan Beam, The Ohio State University Matthew Schneider is a UT Austin student studying Computer Science and currently riding to Alaska on the Sierra team.
July 8, 2016, Filed Under: 2016, cancer, reflections, research, texas4000Engaging the Fight Against Cancer with Texas 4000 “Cancer begins and ends with people. In the midst of scientific abstraction, it is sometimes possible to forget this one basic fact.” –June Goodfield. Before this summer, I viewed the fight against cancer solely as a scientific race to find a cure. As I began my participation in the BME CUReS REU program, my perspective of the fight against cancer has been changed and expanded. Through my research in the lab and reading of Emperor of All Maladies: A Biography of Cancer, I have come to realize that the complexity of the nature of cancer as a disease and its variance among its victims prevents there ever being one single drug that provides a universal cure. Yet, in order to achieve the ultimate goal of eliminating the disease of cancer, it is going to take several different effective treatments. In consequence, winning the war against cancer requires an entire army – a community. A community of researchers to share findings to better the understanding of cancer as a disease and to find more effective treatments. A community of doctors to communicate the needs of patients and the successes and failures of treatments. A community of people to raise the public’s awareness and funds for the fight against cancer. In a community, there are several different groups of individuals who hold various roles, all of which are vital to the functionality of the community. Just as in any functioning body, one part of a community cannot thrive without the other. In the cancer community, doctors and researchers could not collaborate and create effective treatments without funding. It is the individuals of the cancer community that dedicate their time to share their personal encounters with cancer, to host fundraising events, to campaign for government funding, to raise public awareness who come up with the funding. Thus, these are the individuals who fuel the fight against cancer. A great example of such individuals are those who make the Texas4000 happen. These individuals dedicate two years of their life to raise $4,500 total funds for cancer research and to train physically, emotionally, and mentally to ride a bike 4000 miles. The strenuous 4000 mile bike ride from Austin to Anchorage mirrors the exhausting fight cancer patients face every day. While some may ride in memory of someone who encountered cancer as others ride because they personally are a survivors, all ride for the sole purpose of raising hope and public knowledge in the fight against cancer. Without the funds raised by the Texas4000 riders, research programs like BME CUReS would not be happening. Every day in the labs, I use numerous pipet tips, reagents, cell lines, and fancy other equipment – all to better understand cancer. Yet, all these tools wear high price tags. Due to dedication of the Texas4000 individuals, this summer, I can contribute research that will bring the cancer community one step closer to fighting off cancer. -Rachel Hegab, Louisiana Tech University On Friday, July 1, four Texas 4000 riders from the 2017 visited the REU weekly seminar to talk about why they ride: Marc, Margo, Luis, and Valerie. We also made cards for the 2016 Sierra team and will be sending them to the Portland Day 45 mail drop! BME CUReS Cancer Summer Scholars and 2017 Texas 4000 Riders on July 1, 2016 Cards for 2016 Sierra Team!
