Start-up Pursues Intraoperative MRI for Surgeons

Current surgical treatment of the brain starts with MR images taken a few days before surgery. Once in the operating room, multiple cameras track instruments as they are inserted through a hole in the skull, creating images that can be superimposed on the original MR scans, but there is no guarantee that the brain will not shift slightly during the surgery and throw off the best efforts at exact guidance.

As a result, neurosurgeons have discussed a radical way to achieve real-time accuracy in placement: performing surgery with the brain inside an MR machine, says Walter F. Block, PhD, a professor of biomedical engineering at the University of Wisconsin-Madison.

To bring the full promise of MR into the operating room, Block has formed a company called InseRT MRI to develop software that allows surgeons to observe the brain in real time on an MR machine during surgery.

Such a system would have a number of applications, he says. For example, drugs for brain cancer can be delivered over as long as 54 hours. "It would be valuable to see where the drug is going during the first few hours," Block says. "Drugs move at different rates through gray and white matter, and this ability to recalibrate the treatment plan, based on actual data on where the drug is moving, would allow you to alter the location of the catheter or the flow rate of the medication."

To get that accuracy advantage, Block does not envision forcing surgeons to learn a new operating environment. "Surgeons have operating room tools and work stations that are familiar to them," he says. "We are creating a set of tools that make the MR space a comfortable place for the surgeon."

The goal is not to develop software that could be spliced into MR manufacturers' systems, he says, "since every time they alter their software, we would have to change ours." Instead, Block is borrowing tactics from the smartphone industry. "People write apps that use various phone resources — GPS, the screen, the orientation system. We look at the MR scanner as a set of resources that we can control. An app writer does not have to go to Samsung or Apple and say, 'We have this idea.'"

Block says his software will interact with the MR machine through a software "portal" being developed by another firm.

One obvious market is the pharmaceutical industry. "Any drug trial in the brain will cost hundreds of millions of dollars," Block says, "and we often see trials being repeated after post-mortem analysis raises questions about the accuracy of drug placement."

Targeted surgery could also help remove bits of brain tissue to treat severe epilepsy. Marvel Medtech in Cross Plains, Wisconsin, is developing a system that would employ InseRT MRI's guidance to biopsy breast tumors. The technology also raises the potential for localized psychiatric drug therapy, Block says.

In the brain, the MR guidance system is already accurate to less than a millimeter, Block says. While conventional stereotactic systems can approach that accuracy "in the best case," the error can rise to 1.5 or 2 mm — a vast distance in an organ as delicate as the human brain, in which damage to healthy tissue must be minimized.

Source: University of Wisconsin-Madison