Please Note: The 2020 American Physical Society (APS) March Meeting that was to be held in Denver, Colorado from March 2 through March 6 has been canceled. The decision was made late Saturday (February 29), out of an abundance of caution and based on the latest scientific data available regarding the transmission of the coronavirus disease (COVID-19). See our official release on the cancelation for more details.
DENVER, COLO., FEBRUARY 28, 2020--Cancer cells are a product of their environment. The surrounding cells, extracellular matrix, and other features influence disease progression and spread of cancer cells to other parts of the body. Chemical cues like the presence of nutrients and oxygen have been studied for decades, but more recently, researchers have turned their attention to equally important physical cues.
New research on the tumor mechanical microenvironment will be presented at the 2020 American Physical Society March Meeting in Denver. Highlights include a study that looks at how the anisotropy of the extracellular matrix affects cancer cell migration, a novel optical tweezer-based tool that probes mechanical cues, and a model to find the best place within a tumor to inject a chemotherapy drug.
Mechanical Cues Drive Metastasis
Oregon State University researcher Bo Sun will present his findings on the complex interactions between cancer cell migration and the extracellular matrix, a 3D network of collagen, proteins, and other molecules that support the surrounding cells. Specifically, he will discuss the anisotropy of the extracellular matrix, and how a particular alignment of collagen fibers can create a cancer cell superhighway of sorts.
"For most research in the field so far, a dominant paradigm is that rigidity of the tissue environment is the dominant factor that guides cell migration. The cell wants to move to a more rigid region compared to a soft region," said Sun. "We're seeing that a different type of physical property, anisotropy of the environment, is more efficient in terms of guiding cell migration."
For instance, collagen fibers aligned circumferentially around the tumor causes the cancer cells to become trapped by this alignment, whereas fibers arranged radially provide a frictionless highway for cells to migrate outward. Studying the way cells move in their environment--and what factors drive that movement--has implications for understanding how cancer cells infiltrate new areas of the body.
Probing Tissues with Optical Tweezers
Biophysicist Kandice Tanner has repurposed a tool to measure the mechanical cues that may influence how tumor cells disseminate to different organs. The optical tweezer-based technique can probe the physical properties of cells in living animals with microscale resolution.
"Previously, characterization of mechanical properties of tissues, cells, and extracellular matrix hydrogels were mainly obtained using bulk rheological or nanometer scale techniques such as atomic force microscopy and primarily for in vitro systems," said Tanner, an investigator at the National Cancer Institute, part of the National Institutes of Health. "These techniques are useful to assess material properties but do not possess the resolution that is needed to resolve length scales that are compatible with the micron-size protrusions used by cells to respond to external cues."
Tanner and her colleagues employed the technique to measure the viscoelastic properties of tissue in living zebrafish and 3D culture models of breast cancer progression. For the latter project, they used optical trap-based active microrheology to map internal cellular and external extracellular matrix mechanics with near simultaneity. They found that, unlike healthy cells, breast tumor cells do not match their mechanical properties to the surrounding microenvironment.
"As cancer cells migrate from their original primary tumor, they encounter many physical cues before establishing new lesions in different organs such as the patient's bones, brain, liver, or lungs," said Tanner. "We believe that by decoding the role of the physical cues, we can understand why some tumor cells are able to colonize one organ versus the other."
Modeling Cancer Drug Response
Cancer treatment relies heavily on trial and error, which can lead to unnecessary toxicity and cost. Models that predict how a cancer drug will diffuse throughout the tumor offer a possible solution for oncologists. Aminur Rahman develops these kinds of mechanistic models of drug response as a method for oncologists to choose the most effective treatment before administering any medication.
"Our mechanistic models are able to produce dose-response curves that oncologists would see from cell line and drug data pairs," said Rahman, a post-doctoral researcher at Texas Tech University. "We realized that perhaps this research could be used for computer-aided treatment strategies."
He will present the results of multiple projects in a poster presentation. The first investigates a model of drug distribution after injection directly into a solid tumor and its effect on cancer cell death. While the model assumes the tumor is spherical and homogeneous, brain tumors in particular tend to be highly inhomogeneous and anisotropic. The second study develops a more sophisticated computational model for inhomogeneous-anisotropic drug diffusion using real-world diffusion tensor MRI data.
"Because of the tumor's inhomogeneity and anisotropy, the center might not be the best place to inject drugs," said Rahman. "We looked at different injection sites, and it was not necessary the center that would do the trick. In such cases, having a model would help an oncologist know where to inject the drug."
The Nematic Feedback Between Cancer Cells and the Extracellular Matrix
TIME/DATE/PLACE: 8:00 AM, Monday, March 2, 2020, Room: 403
CONTACT: Bo Sun, firstname.lastname@example.org
The Role of Tissue Biophysics in Organ Selectivity in Metastasis
TIME/DATE/PLACE: 9:24 AM, Monday, March 2, 2020, Room: 403
CONTACT: Kandice Tanner, email@example.com
Physics-Based Models and Simulations of Cancer Drug Response in Solid Tumors
TIME/DATE/PLACE: 2:00 PM, Monday, March 2, 2020, Room: Exhibit Hall C/D
CONTACT: Aminur Rahman, firstname.lastname@example.org
ABOUT THE MEETING
The American Physical Society (APS) March Meeting is a major international conference and the largest physics meeting of the year. In 2020, the APS March Meeting will convene from March 2-6 at the Colorado Convention Center in downtown Denver.
Meeting website: https://march.aps.org/
Scientific program: http://meetings.aps.org/Meeting/MAR20/APS_epitome
Press services: https://march.aps.org/services/press/
Hotel & Travel information: https://march.aps.org/travel/
Complimentary registration is available to journalists for the express purpose of gathering and reporting news and information from the meeting. Staff reporters, freelance writers, and students are welcome to apply. Press credentials may be obtained by completing the form on this page: https://march.aps.org/services/press/. The deadline for press registration is Friday February 28th at 3:00 p.m. EST.
All press conferences will take place in Room 608. If you are unable to attend, you may register to watch and ask questions online at https://webcast.apswebcasting.com/webcast/registration/a65e0a8e-38c6-4ccd-8eea-98696d213857
A press room for registered journalists will operate throughout the meeting in Room 610/612 and will offer complimentary coffee, breakfast, and lunch. The press room may be reserved for conducting interviews.
Monday - Thursday, 7:30 a.m. - 6:00 p.m.
Friday, 7:30 a.m. - 2:45 p.m.
Please contact the APS Press Office with any questions at email@example.com.
The American Physical Society is a nonprofit membership organization working to advance and diffuse the knowledge of physics through its outstanding research journals, scientific meetings, and education, outreach, advocacy, and international activities. APS represents over 55,000 members, including physicists in academia, national laboratories, and industry in the United States and throughout the world. Society offices are located in College Park, Maryland (Headquarters), Ridge, New York, and Washington, D.C.