A Canadian hospital is launching a court challenge with the ultimate goal of invalidating patents on human genes, saying such protection can adversely affect the health of patients and boost the country’s health-care costs.
Lawyers for the Children’s Hospital of Eastern Ontario, or CHEO, were in the process early Monday of filing the challenge in federal court in Ottawa, arguing that genes and other segments of the human genome should not be subject to patents for commercial or any other purposes.
“The core position really is that no one should be able to patent human DNA,” said Alex Munter, president and CEO of the Ottawa-based CHEO. “It would be like patenting water or air.”
Companies or other institutions that hold patents on genes or snippets of DNA and own the rights to diagnostic tests developed using that genetic information have a monopoly on what can be done with the information.
Last year, the U.S. Supreme Court ruled that naturally occurring human DNA cannot be patented, siding with advocates who argued that the multibillion-dollar biotechnology industry should not have exclusive control over genetic information found inside the human body.
But in Canada, there has been no similar court challenge to the country’s Patent Act — and hence no ruling, said Richard Gold, a professor of law at McGill University in Montreal.
“There’s considerable lack of clarity in Canada, especially after the U.S. decision about exactly what can be patented,” said Gold, who is consulting pro bono on the case, but is not involved in the actual court challenge.
“So we have companies not knowing whether their patents are valid. We have hospitals and governments not willing to take the risk, because it would cost a lot to defend one of these actions,” he said, referring to potential law suits based on patent infringement.
“To take the risk, they may be violating the patents.”
CHEO’s court challenge centres on the patent for genes related to what’s known as long QT syndrome, a potentially deadly heart rhythm disorder that runs in families.
“It’s quite an insidious condition because long QT syndrome can be difficult to diagnose with an ECG (electrocardiogram),” said Dr. Gail Graham, chief of the hospital’s regional genetics program. “Typically it’s the first-line test, but many people’s look normal even with an inherited predisposition.”
“So ECG isn’t a perfect tool and it needs to be combined with genetic testing, which has a much higher sensitivity.”
There are a number of genes related to long QT syndrome, and five of them have been patented, primarily by the University of Utah, the chief defendant in the court challenge.
Patents cover the DNA sequence — either the whole gene or part of the gene — and the diagnostic test, said Gold.
The court challenge is using patents involving long QT genes as a test case, in the hope of setting precedent that would invalidate all patents on naturally occurring human DNA, he said.
“The patents are on the books, they’re ostensibly valid, but there are strong legal arguments to make that they’re actually not valid or don’t apply.”
Graham said CHEO and some other institutions have advanced genetic testing capabilities with the development of “whole-exome” sequencing technology, which can look at all the roughly 23,000 genes contained in human DNA and pinpoint those mutated genes known to be associated with disease.
The technology, which is currently being validated, could be used to determine whether a sick newborn in the NICU, for instance, has a genetic disorder, by analyzing DNA in a blood sample, said Graham.
“If by chance I happened to read through a long QT gene and found that that ill newborn would also have long QT syndrome, I would be prohibited from learning that, our laboratory would be prohibited from learning that and our patients would be prohibited from learning that,” she said.
“So we would actually be in the morally reprehensible position of not being able to potentially save someone’s life and the family members’ lives because someone has claimed a patent on a sequence of DNA that occurs naturally.”
Graham said long QT syndrome can cause fainting spells during exercise, seizures or in some cases, or sudden death. Genetic testing can identify family members at risk for the condition, allowing them to be treated with medications and sometimes an implanted defibrillator.
As it stands, hospitals must send a patient’s blood sample to be tested for long QT gene mutations to one of the U.S. labs licensed by the University of Utah.
The U.S. labs charge between $3,800 and $4,000 for a test, more than double what it would cost in Canada, said Graham. In Ontario alone, such tests cost the system about $200,000.
“So there’s a significant impact on the health-care system.”
There are about 7,000 genetic diseases, and many of the mutated genes that underpin the disorders have not yet been identified. Should newly discovered genes be patented — along with diagnostic tests — the impact on Canada’s health-care system would accumulate, she said.
“We’ll be sending to the U.S. for more and more tests. If you consider the impact of new gene patents and the fact that we might be forced to send blood samples for a number of other conditions over the longer term, it could easily be millions of dollars.”
“We need to be able to take advantage of the great potential that these new technologies have,” Graham said of whole-exome analysis. “And gene patents have the ability to prevent us from doing that.”