Can Genetic Testing Help Shed Light on the Autism Epidemic?
Autism cases are still on the rise, and scientists don't know why. In April, the Centers for Disease Control (CDC) reported that rates of autism had increased once again, now at an estimated 1 in 59 children up from 1 in 68 just two years ago. Rates have been climbing steadily since 2007 when the CDC initially estimated that 1 in 150 children were on the autism spectrum.
Some clinicians are concerned that the creeping expansion of autism is causing the diagnosis to lose its meaning.
The standard explanation for this increase has been the expansion of the definition of autism to include milder forms like Asperger's, as well as a heightened awareness of the condition that has improved screening efforts. For example, the most recent jump is attributed to children in minority communities being diagnosed who might have previously gone under the radar. In addition, more federally funded resources are available to children with autism than other types of developmental disorders, which may prompt families or physicians to push harder for a diagnosis.
Some clinicians are concerned that the creeping expansion of autism is causing the diagnosis to lose its meaning. William Graf, a pediatric neurologist at Connecticut Children's Medical Center, says that when a nurse tells him that a new patient has a history of autism, the term is no longer a useful description. "Even though I know this topic extremely well, I cannot picture the child anymore," he says. "Use the words mild, moderate, or severe. Just give me a couple more clues, because when you say autism today, I have no idea what people are talking about anymore."
Genetic testing has emerged as one potential way to remedy the overly broad label by narrowing down a heterogeneous diagnosis to a specific genetic disorder. According to Suma Shankar, a medical geneticist at the University of California, Davis, up to 60 percent of autism cases could be attributed to underlying genetic causes. Common examples include Fragile X Syndrome or Rett Syndrome—neurodevelopmental disorders that are caused by mutations in individual genes and are behaviorally classified as autism.
With more than 500 different mutations associated with autism, very few additional diagnoses provide meaningful information.
Having a genetic diagnosis in addition to an autism diagnosis can help families in several ways, says Shankar. Knowing the genetic origin can alert families to other potential health problems that are linked to the mutation, such as heart defects or problems with the immune system. It may also help clinicians provide more targeted behavioral therapies and could one day lead to the development of drug treatments for underlying neurochemical abnormalities. "It will pave the way to begin to tease out treatments," Shankar says.
When a doctor diagnoses a child as having a specific genetic condition, the label of autism is still kept because it is more well-known and gives the child access to more state-funded resources. Children can thus be diagnosed with multiple conditions: autism spectrum disorder and their specific gene mutation. However, with more than 500 different mutations associated with autism, very few additional diagnoses provide meaningful information. What's more, the presence or absence of a mutation doesn't necessarily indicate whether the child is on the mild or severe end of the autism spectrum.
Because of this, Graf doubts that genetic classifications are really that useful. He tells the story of a boy with epilepsy and severe intellectual disabilities who was diagnosed with autism as a young child. Years later, Graf ordered genetic testing for the boy and discovered that he had a mutation in the gene SYNGAP1. However, this knowledge didn't change the boy's autism status. "That diagnosis [SYNGAP1] turns out to be very specific for him, but it will never be a household name. Biologically it's good to know, and now it's all over his chart. But on a societal level he still needs this catch-all label [of autism]," Graf says.
"It gives some information, but to what degree does that change treatment or prognosis?"
Jennifer Singh, a sociologist at Georgia Tech who wrote the book Multiple Autisms: Spectrums of Advocacy and Genomic Science, agrees. "I don't know that the knowledge gained from just having a gene that's linked to autism," is that beneficial, she says. "It gives some information, but to what degree does that change treatment or prognosis? Because at the end of the day you have to address the issues that are at hand, whatever they might be."
As more children are diagnosed with autism, knowledge of the underlying genetic mutation causing the condition could help families better understand the diagnosis and anticipate their child's developmental trajectory. However, for the vast majority, an additional label provides little clarity or consolation.
Instead of spending money on genetic screens, Singh thinks the resources would be better used on additional services for people who don't have access to behavioral, speech, or occupational therapy. "Things that are really going to matter for this child in their future," she says.
Short-Term Suspended Animation for Humans Is Coming Soon
At 1 a.m., Tony B. is flown to a shock trauma center of a university hospital. Five minutes earlier, he was picked up unconscious with no blood pressure, having suffered multiple gunshot wounds with severe blood loss. Standard measures alone would not have saved his life, but on the helicopter he was injected with ice-cold fluids intravenously to begin cooling him from the inside, and given special drugs to protect his heart and brain.
Suspended animation is not routine yet, but it's going through clinical trials at the University of Maryland and the University of Pittsburgh.
A surgeon accesses Tony's aorta, allowing his body to be flushed with larger amounts of cold fluids, thereby inducing profound hypothermia -- a body temperature below 10° C (50° F). This is suspended animation, a form of human hibernation, but officially the procedure is called Emergency Preservation and Resuscitation for Cardiac Arrest from Trauma (EPR-CAT).
This chilly state, which constitutes the preservation component of Tony's care, continues for an hour as surgeons repair injuries and connect his circulation to cardiopulmonary bypass (CPB). This allows blood to move through the brain delivering oxygen at low doses appropriate for the sharply reduced metabolic rate that comes with the hypothermia, without depending on the heart and lungs. CPB also enables controlled, gradual re-warming of Tony's body as fluid and appropriate amounts of red blood cells are transfused into him.
After another hour or so, Tony's body temperature reaches the range of 32-34° C (~90-93° F), called mild hypothermia. Having begun the fluid resuscitation process already, the team stops warming Tony, switches his circulation from CPB to his own heart and lungs, and begins cardiac resuscitation with electrical jolts to his heart. With his blood pressure stable, his heart rate slow but appropriate for the mild hypothermia, Tony is maintained at this intermediate temperature for 24 hours; this last step is already standard practice in treatment of people who suffer cardiac arrest without blood loss trauma.
The purpose is to prevent brain damage that might come with the rapid influx of too much oxygen, just as a feast would mean death to a starvation victim. After he is warmed to a normal temperature of 37° C (~99° F), Tony is awakened and ultimately recovers with no brain damage.
Tony's case is fictional; EPR-CAT is not routine yet, but it's going through clinical trials at the University of Maryland and the University of Pittsburgh, under the direction of trauma surgeon Dr. Samuel Tisherman, who spent many years developing the procedure in dogs and pigs. In such cases, patients undergo suspended animation for a couple of hours at most, but other treatments are showing promise in laboratory animals, like the use of hydrogen sulfide gas without active cooling to induce suspended animation in mice. Such interventions could ultimately fuse with EPR-CAT, sending the new technology further into what's still the realm of science fiction – at least for now.
Consider the scenario of a 5-year-old girl diagnosed with a progressive, incurable, terminal disease.
Experts say that extended suspended animation – cooling patients in a stable state for months or years -- could be possible at some point, although no one can predict when the technology will be clinical reality, since hydrogen sulfide and other chemical tactics would have to move into clinical use in humans and prove safe and effective in combination with EPR-CAT, or with a similar cooling approach.
How Could Long-Term Suspended Animation Impact Humanity?
Consider the scenario of a 5-year-old girl diagnosed with a progressive, incurable, terminal disease. Since available treatments would only lengthen the projected survival by a year, she is placed into suspended animation. She is revived partially every few years, as new treatments become available that can have a major impact on her disease. After 35 years of this, she is revived completely as treatments are finally adequate to cure her condition, but biologically she has aged only a few months. Physically, she is normal now, though her parents are in their seventies, and her siblings are grown and married.
Such hypothetical scenarios raise many issues: Where will the resources come from to take care of patients for that long? Who will pay? And how will patients adapt when they emerge into a completely different world?
"Heavy resource utilization is a factor if you've got people hibernating for years or decades," says Bradford Winters, an associate professor of anesthesiology and critical care medicine, and assistant professor of neurological surgery at Johns Hopkins.
Conceivably, special high-tech facilities with robots and artificial intelligence watching over the hibernators might solve the resource issue, but even then, Winters notes that long-term hibernation would entail major disparities between the wealthy and poor. "And then there is the psychological effect of being disconnected from one's family and society for a generation or more," he says. "What happens to that 5-year-old waking to her retired parents and married siblings? Will her younger sister adopt her? What would that be like?"
Probably better than dying is one answer.
Back on Earth, human hibernation would raise daunting policy questions that may take many years to resolve.
Outside of medicine, one application of human hibernation that has intrigued generations of science fiction writers is in long-duration space travel. During a voyage lasting years or decades, space explorers or colonists not only could avoid long periods of potential boredom, but also the aging process. Considering that the alternative to "sleeper ships" would be multi-generation starships so large that they'd be like small worlds, human hibernation in spaceflight could become an enabling technology for interstellar flight.
Big Questions: It's Not Too Early to Ask
Back on Earth, the daunting policy questions may take many years to resolve. Society ought to be aware of them now, before human hibernation technology outpaces its dramatic implications.
"Our current framework of ethical and legal regulation is adequate for cases like the gunshot victim who is chilled deeply for a few hours. Short-term cryopreservation is currently part of the continuum of care," notes David N. Hoffman, a clinical ethicist and health care attorney who teaches at Columbia University, and at Yeshiva University's Benjamin N. Cardozo School of Law and Albert Einstein College of Medicine.
"But we'll need a new framework when there's a capability to cryopreserve people for many years and still bring them back. There's also a legal-ethical issue involving the parties that decide to put the person into hibernation versus the patient wishes in terms of what risk benefit ratio they would accept, and who is responsible for the expense and burdens associated with cases that don't turn out just right?"
To begin thinking about practical solutions, Hoffman characterizes long-term human hibernation as an extension of the ethics of cyro-preserved embryos that are held for potential parents, often for long periods of time. But the human hibernation issue is much more complex.
"The ability of the custodian and patient to enter into a meaningful and beneficial arrangement is fraught, because medical advances necessary to address the person's illness or injury are -- by definition -- unknown," says Hoffman. "It means that you need a third party, a surrogate, to act on opportunities that the patient could never have contemplated."
Such multigenerational considerations might become more manageable, of course, in an era when gene therapy, bionic parts, and genetically engineered replacement organs enable dramatic life extension. But if people will be living for centuries regardless of whether or not they hibernate, then developing the medical technology may be the least of the challenges.
The Mind-Blowing Promise of Neural Implants
You may not have heard of DARPA, the research branch of the Pentagon. But you're definitely familiar with some of the technology it has pioneered, like the Internet, Siri, and handheld GPS.
"Now we're going to try to go from this proof-of-concept all the way to commercial technologies that can powerfully affect patients' lives."
Last week in National Harbor, Maryland, DARPA celebrated its 60th anniversary by showcasing its latest breakthroughs and emerging research programs, one of which centers around using neurotechnology to enhance the capabilities of the human brain. This technology is initially being developed to help warfighters and veterans, but its success could have enormous implications for civilian patients and, eventually, mainstream consumers.
The field is moving ahead rapidly. Fifteen years ago, a monkey named Aurora used a brain-machine interface to control a cursor on a computer screen. In 2014, DARPA's mind-controlled prosthetic arm for amputees won approval from the Food and Drug Administration.
Since then, DARPA has continued to push neurotechnology to new heights. Here are three of their research programs that are showing promise in early human testing:
1) A NEURAL IMPLANT HELP MANAGE PSYCHIATRIC ILLNESS
More than 2.2 million veterans and 44 million civilians are living with some form of psychiatric illness, and medications don't work for everyone. DARPA set out to create new options for people living with debilitating anxiety, depression, and PTSD.
"We can get somebody back to normal. It's a whole new set of tools for physicians," said Justin Sanchez, Director of the Biological Technologies Office at DARPA.
He told the audience about a woman living with both epilepsy and extreme anxiety, who has a direct neural interface that reads her brain's signals in real time and can be modulated with stimulation. He shared a recent video of her testing the device:
"Now we're going to try to go from this proof-of-concept all the way to commercial technologies that can powerfully affect patients' lives," Sanchez said.
2) A NEURAL IMPLANT TO HELP IMPROVE MEMORY
"We are right at the cusp" of improving memory recall with direct neural interfaces, Sanchez said.
All day long, our brains shift between poor and good memory states. A brain-computer interface can read the signals of populations of neurons in the lateral temporal cortex. The device continuously monitors the state of the brain and delivers stimulation within a fraction of a second after detecting a poor memory state, to improve the person's memory performance.
The improved memory lasts only seconds, so the system "delivers stimulation as needed in a closed loop to keep the performance in a good state, because of this natural variability of performance," said Dan Rizzuto, founder of NiaTherapeutics, whose technology was developed with support from DARPA and the United States BRAIN Initiative.
Check out this recently shot video of a patient testing the device, which Sanchez called "a breakthrough moment":
About 400 patients have been tested with this technology so far. In a pilot study whose data have not yet been published, patients with traumatic brain injury showed improvement in recall of around 28 percent, according to Rizzuto.
He estimates that potential FDA approval of the device for patients with traumatic brain injury is still 7 to 8 years away. The technology holds the potential to help many other kinds of patients as well.
"We believe this device could also be used to treat Alzheimer's because it's not specific to any brain pathology but based on a deep understanding of the way human memory works," Rizzuto said.
3) A NEURAL IMPLANT TO REVOLUTIONIZE PROSTHETICS FOR WARFIGHTERS AND VETERANS
Since 2006, DARPA has run a program to revolutionize prosthetics. The latest advances allow amputees to actually feel again with their bionic limbs.
Sensors in a prosthetic hand relay information to an interface in the brain that allows the person to detect which of their "fingers" are being touched, while their eyes are closed:
WHAT COMES NEXT?
DARPA is now turning its attention to non-surgical, non-invasive neurotechnology. Researchers hope to use advanced sensor technology to detect signals from neurons without putting any electrodes directly inside the brain. Under the direction of program manager Dr. Al Emondi, the N³ program is about to launch soon and plans to run for four or five years.
"We haven't even scratched the surface of what a human brain's capability is," said Dr. Geoffrey Ling, the Founding Director of the Biological Technologies Office. "When we can make this a non-invasive consumer technology, this will explode. It will take on a life of its own."
Then, inevitably, the hard questions will follow.
As Sanchez put it: "Will society consider some form of neural enhancement a personal choice like braces? Could there be a disturbing gap for people who have neurotech and those who don't? We must come together and all think over the horizon. How the story unfolds ultimately depends on all of us."
Kira Peikoff was the editor-in-chief of Leaps.org from 2017 to 2021. As a journalist, her work has appeared in The New York Times, Newsweek, Nautilus, Popular Mechanics, The New York Academy of Sciences, and other outlets. She is also the author of four suspense novels that explore controversial issues arising from scientific innovation: Living Proof, No Time to Die, Die Again Tomorrow, and Mother Knows Best. Peikoff holds a B.A. in Journalism from New York University and an M.S. in Bioethics from Columbia University. She lives in New Jersey with her husband and two young sons. Follow her on Twitter @KiraPeikoff.