Omar Khan, M.D.
A groundbreaking study in multiple sclerosis focusing on “remyelination in the brain” has been initiated by Omar Khan, M.D., professor and chair of neurology at the Wayne State University School of Medicine.
"This is a novel approach in the treatment of multiple sclerosis, which is characterized by diffuse demyelination and axonal loss in the central nervous system,” said Dr. Khan, who also serves as director of the Multiple Sclerosis Center and director of the Sastry Foundation Advanced Imaging Laboratory. “In this study, we are targeting remyelination in the central nervous system.”
Dr. Khan noted that there are 10 United States Food and Drug Administration-approved treatments for multiple sclerosis, none with any well-characterized reparative or remyelinating potential. Those treatments primarily focus on altering the behavior of the immune system and target inflammation.
However, this new approach targets remyelination in the central nervous system using a humanized monoclonal antibody that binds to the semaphorin 4D, a member of the semaphorin family of proteins and an important mediator of axonal growth cone guidance. Semaphorin-induced signaling also has been shown to induce growth cone collapse of neurons and apoptosis of neural precursors, and to induce process extension collapse and apoptosis of oligodendrocytes. Semaphorins consist of a family of soluble and membrane-bound proteins that were originally defined as axonal-guidance factors. These proteins play important roles in establishing precise connections between neurons and their appropriate targets.
“Therefore, it is a plausible target with the realistic goal of achieving remyelination,” Dr. Khan said. “This is a paradigm shift and the start of the next generation of therapies to treat multiple sclerosis that will change its focus to repair rather than inflammation.”
The brain can largely be divided into gray and white areas. Neurons are located in the gray area, and the white parts are where neurons send their axons – similar to electrical cables carrying messages – to communicate with other neurons and bring messages from the brain to muscles. The white parts of the brain are white because a cell type called oligodendrocytes makes a cholesterol-rich membrane called myelin that coats the axons. The myelin’s function is to insulate the axons, similar to the plastic sheath coating electrical cables. In addition, the myelin speeds communication along axons and makes that communication more reliable. In patients with MS, their immune system attacks the myelin sheathing. The subsequent degradation leads to the messages from the brain to other parts of the body leaking and derailing from their intended target.
Restoring the myelin sheathing is the goal of Dr. Khan’s new study.
The Wayne State University Multiple Sclerosis Center, in collaboration with Vaccinex, a privately-held biotechnology company headquartered in Rochester, N.Y., initiated this early stage dose-defining study.
“If successful, this will lead to large scale studies with this molecule targeting remyelination in the brain as a primary focus, detected by advanced imaging techniques such as magnetization transfer ratio,” Dr. Khan said. “The real challenge will be to reverse or reduce conduction blocks in the demyelinated nerve that may translate into neurologic improvement. If we could achieve that with this approach, it opens the door for hundreds of thousands of multiple sclerosis patients for whom no therapy is currently effective. This may also provide a unique opportunity in combining therapies with different mechanistic approaches.”
WSU is home to the largest MS center in Michigan and among the 10 sites in the world undertaking this translational initiative. The center is among the top five MS centers in the U. S., with more than 4,000 patients. The center is involved in cutting-edge immunologic, genetic, MR imaging and therapeutic studies.
Dr. Khan said only three molecules in the world, including this monoclonal antibody, are being investigated in patients with multiple sclerosis that focus on remyelination.
“It is humbling to lead such a unique groundbreaking effort and that Wayne State University is one of the few centers in the world that are participating in this next true generation translational research,” he said. “The patients are observed over night at Harper University Hospital, which has been a great partner in facilitating this research endeavor.”
Multiple sclerosis affects more than 500,000 people (or one in 600) in the U.S. and more than 2 million worldwide. After trauma, it is the most common cause of disability in young adults. While there is no cure, several treatments are approved for the relapsing form of multiple sclerosis that reduces the frequency of flare-ups and slows disease progression.