Case Western Reserve University researchers use magnets and new device to isolate disease-fighting T cells
, which uses a patient鈥檚 own modified immune cells to find and destroy cancer cells, can produce dramatic results when treating blood cancers, such as lymphoma and leukemia, and shows promise against solid tumors.
But harvesting T cells, a type of white blood cell that helps the immune system fight germs and protect against disease, is difficult and expensive鈥攍imiting the use of this potentially life-saving therapy to major cancer centers and only after other treatments have failed.
Now a team of researchers at is developing a new device to harvest T cells that might make CAR T cell therapy less expensive and more widely available. The device, called CAPGLO (for capture and glow), uses a magnetic field to 鈥渃apture鈥� T cells and visualize them with fluorescent tags that make them 鈥済low.鈥�
The laboratories of , a physicist at the College of Arts and Sciences, Susann Brady-Kalnay, a cell biologist at the School of Medicine, and David Wald, an immunologist at the School of Medicine, reached across disciplines and schools to collaborate on this technological innovation.
鈥淚 hope that we could bring the cost of immunotherapy down so it could be first-line therapy rather than end-stage treatment,鈥� said Brady-Kalnay, the Sally S. Morley Designated Professor of Brain Tumor Research and a member of the (Case CCC). 鈥淔or some people, this is a curative therapy. For others it offers significant survival benefits. We need to make it more accessible to everyone.鈥�
CAPGLO is expected to be very inexpensive to manufacture. 鈥淚f we can really do it, for a few hundred dollars rather than thousands or hundreds of thousands, that鈥檚 where this treatment reaches equity,鈥� said Brown, a Distinguished University Professor and Institute Professor of physics.
As co-leader of the Immune Oncology Program, Wald directs the Case CCC clinical Cell Therapy Lab that manufactures CAR T cell therapies for patients. He has developed an ultra-fast procedure to establish and expand CAR T cells in less than 24 hours.
Conventionally harvesting T cells
T cells are extracted from a cancer patient鈥檚 blood using 鈥渓eukapheresis,鈥� where blood is removed and centrifuged to harvest immune cells and then returned to the patient. This requires specialized equipment, costing hundreds of thousands of dollars, as well as removing and replacing a large volume of blood.
The cells are then transformed into cancer killers in the lab by adding a protein called a chimeric antigen receptor, or CAR. These cells鈥攏ow called CAR T cells鈥攁re multiplied in the lab and reinfused into the patient鈥檚 bloodstream within a few days to weeks. The CAR protein acts like a navigation system to help track down and kill cancer cells. For some patients with even very advanced cancers, CAR T cell therapy can eradicate their disease.
CAPGLO wouldn鈥檛 require more than about a half-pint of a patient鈥檚 blood鈥攖he amount typically needed when donating blood.
This isn鈥檛 Brown鈥檚 first foray into the physics of blood. He and Case Western Reserve senior research associate Robert Deissler developed a technique to diagnose malaria that relies on the fact that malaria-infected blood carries extra iron鈥攁s iron-containing crystals, which are magnetic. This simple diagnostic tool using magnets to detect malaria in blood samples earned them a Patent for Humanity in 2016 from the U.S. Patent and Trademark Office, an award recognizing innovators for game-changing technology that meets global humanitarian challenges.
Using magnets to isolate T cells
For this new project, the researchers make the T cells magnetic. Kathleen Molyneaux, a senior research associate in Brady-Kalnay鈥檚 lab, coats tiny magnetic beads with a protein designed to snag T cells in a blood sample and bind them to the bead鈥檚 surface.
Then, using CAPGLO and a magnetic field, Brown and Deissler can separate the magnetized T cells from the red blood cells and plasma, collecting the T cells in a small tube.
As a final step, the investigators plan to harmlessly snip off the beads, leaving a population of T cells ready for chimeric transduction in Wald鈥檚 lab. The goal is to take and process a patient鈥檚 blood within an hour, so the T cells don鈥檛 become damaged.
The researchers received a grant from the CWRU Technology Validation and Startup Fund, a program supported by the , to explore the viability of the technology.
For more information, please contact Diana Steele at [email protected].