Bad Actors Getting Your Health Data Is the FBI’s Latest Worry
A hacker activating a 3D rendering of DNA data.
In February 2015, the health insurer Anthem revealed that criminal hackers had gained access to the company's servers, exposing the personal information of nearly 79 million patients. It's the largest known healthcare breach in history.
FBI agents worry that the vast amounts of healthcare data being generated for precision medicine efforts could leave the U.S. vulnerable to cyber and biological attacks.
That year, the data of millions more would be compromised in one cyberattack after another on American insurers and other healthcare organizations. In fact, for the past several years, the number of reported data breaches has increased each year, from 199 in 2010 to 344 in 2017, according to a September 2018 analysis in the Journal of the American Medical Association.
The FBI's Edward You sees this as a worrying trend. He says hackers aren't just interested in your social security or credit card number. They're increasingly interested in stealing your medical information. Hackers can currently use this information to make fake identities, file fraudulent insurance claims, and order and sell expensive drugs and medical equipment. But beyond that, a new kind of cybersecurity threat is around the corner.
Mr. You and others worry that the vast amounts of healthcare data being generated for precision medicine efforts could leave the U.S. vulnerable to cyber and biological attacks. In the wrong hands, this data could be used to exploit or extort an individual, discriminate against certain groups of people, make targeted bioweapons, or give another country an economic advantage.
Precision medicine, of course, is the idea that medical treatments can be tailored to individuals based on their genetics, environment, lifestyle or other traits. But to do that requires collecting and analyzing huge quantities of health data from diverse populations. One research effort, called All of Us, launched by the U.S. National Institutes of Health last year, aims to collect genomic and other healthcare data from one million participants with the goal of advancing personalized medical care.
Other initiatives are underway by academic institutions and healthcare organizations. Electronic medical records, genetic tests, wearable health trackers, mobile apps, and social media are all sources of valuable healthcare data that a bad actor could potentially use to learn more about an individual or group of people.
"When you aggregate all of that data together, that becomes a very powerful profile of who you are," Mr. You says.
A supervisory special agent in the biological countermeasures unit within the FBI's weapons of mass destruction directorate, it's Mr. You's job to imagine worst-case bioterror scenarios and figure out how to prevent and prepare for them.
That used to mean focusing on threats like anthrax, Ebola, and smallpox—pathogens that could be used to intentionally infect people—"basically the dangerous bugs," as he puts it. In recent years, advances in gene editing and synthetic biology have given rise to fears that rogue, or even well-intentioned, scientists could create a virulent virus that's intentionally, or unintentionally, released outside the lab.
"If a foreign source, especially a criminal one, has your biological information, then they might have some particular insights into what your future medical needs might be and exploit that."
While Mr. You is still tracking those threats, he's been traveling around the country talking to scientists, lawyers, software engineers, cyber security professionals, government officials and CEOs about new security threats—those posed by genetic and other biological data.
Emerging threats
Mr. You says one possible situation he can imagine is the potential for nefarious actors to use an individual's sensitive medical information to extort or blackmail that person.
"If a foreign source, especially a criminal one, has your biological information, then they might have some particular insights into what your future medical needs might be and exploit that," he says. For instance, "what happens if you have a singular medical condition and an outside entity says they have a treatment for your condition?" You could get talked into paying a huge sum of money for a treatment that ends up being bogus.
Or what if hackers got a hold of a politician or high-profile CEO's health records? Say that person had a disease-causing genetic mutation that could affect their ability to carry out their job in the future and hackers threatened to expose that information. These scenarios may seem far-fetched, but Mr. You thinks they're becoming increasingly plausible.
On a wider scale, Kavita Berger, a scientist at Gryphon Scientific, a Washington, D.C.-area life sciences consulting firm, worries that data from different populations could be used to discriminate against certain groups of people, like minorities and immigrants.
For instance, the advocacy group Human Rights Watch in 2017 flagged a concerning trend in China's Xinjiang territory, a region with a history of government repression. Police there had purchased 12 DNA sequencers and were collecting and cataloging DNA samples from people to build a national database.
"The concern is that this particular province has a huge population of the Muslim minority in China," Ms. Berger says. "Now they have a really huge database of genetic sequences. You have to ask, why does a police station need 12 next-generation sequencers?"
Also alarming is the potential that large amounts of data from different groups of people could lead to customized bioweapons if that data ends up in the wrong hands.
Eleonore Pauwels, a research fellow on emerging cybertechnologies at United Nations University's Centre for Policy Research, says new insights gained from genomic and other data will give scientists a better understanding of how diseases occur and why certain people are more susceptible to certain diseases.
"As you get more and more knowledge about the genomic picture and how the microbiome and the immune system of different populations function, you could get a much deeper understanding about how you could target different populations for treatment but also how you could eventually target them with different forms of bioagents," Ms. Pauwels says.
Economic competitiveness
Another reason hackers might want to gain access to large genomic and other healthcare datasets is to give their country a leg up economically. Many large cyber-attacks on U.S. healthcare organizations have been tied to Chinese hacking groups.
"This is a biological space race and we just haven't woken up to the fact that we're in this race."
"It's becoming clear that China is increasingly interested in getting access to massive data sets that come from different countries," Ms. Pauwels says.
A year after U.S. President Barack Obama conceived of the Precision Medicine Initiative in 2015—later renamed All of Us—China followed suit, announcing the launch of a 15-year, $9 billion precision health effort aimed at turning China into a global leader in genomics.
Chinese genomics companies, too, are expanding their reach outside of Asia. One company, WuXi NextCODE, which has offices in Shanghai, Reykjavik, and Cambridge, Massachusetts, has built an extensive library of genomes from the U.S., China and Iceland, and is now setting its sights on Ireland.
Another Chinese company, BGI, has partnered with Children's Hospital of Philadelphia and Sinai Health System in Toronto, and also formed a collaboration with the Smithsonian Institute to sequence all species on the planet. BGI has built its own advanced genomic sequencing machines to compete with U.S.-based Illumina.
Mr. You says having access to all this data could lead to major breakthroughs in healthcare, such as new blockbuster drugs. "Whoever has the largest, most diverse dataset is truly going to win the day and come up with something very profitable," he says.
Some direct-to-consumer genetic testing companies with offices in the U.S., like Dante Labs, also use BGI to process customers' DNA.
Experts worry that China could race ahead the U.S. in precision medicine because of Chinese laws governing data sharing. Currently, China prohibits the exportation of genetic data without explicit permission from the government. Mr. You says this creates an asymmetry in data sharing between the U.S. and China.
"This is a biological space race and we just haven't woken up to the fact that we're in this race," he said in January at an American Society for Microbiology conference in Washington, D.C. "We don't have access to their data. There is absolutely no reciprocity."
Protecting your data
While Mr. You has been stressing the importance of data security to anyone who will listen, the National Academies of Sciences, Engineering, and Medicine, which makes scientific and policy recommendations on issues of national importance, has commissioned a study on "safeguarding the bioeconomy."
In the meantime, Ms. Berger says organizations that deal with people's health data should assess their security risks and identify potential vulnerabilities in their systems.
As for what individuals can do to protect themselves, she urges people to think about the different ways they're sharing healthcare data—such as via mobile health apps and wearables.
"Ask yourself, what's the benefit of sharing this? What are the potential consequences of sharing this?" she says.
Mr. You also cautions people to think twice before taking consumer DNA tests. They may seem harmless, he says, but at the end of the day, most people don't know where their genetic information is going. "If your genetic sequence is taken, once it's gone, it's gone. There's nothing you can do about it."
Pregnant and Breastfeeding Women Might Have a New Reason to Ditch Artificial Sweeteners
A mom cradles her newborn baby.
Women considering pregnancy might have another reason to drop artificial sweeteners from their diet, if a new study of mice proves to apply to humans as well. It highlights "yet another potential health impact of zero-calorie sweeteners," according to lead author Stephanie Olivier-Van Stichelen.
The discovery was serendipitous, not part of the original study.
It found that commonly used artificial sweeteners consumed by female mice transfer to pups in the womb and later through milk, harming their development. The sweeteners affected the composition of bacteria in the gut of the pups, making them more vulnerable to developing diabetes, and greatly reduced the liver's capacity to neutralize toxins.
The discovery was serendipitous, not part of the original study, says John Hanover, the senior author and a cell biologist at the NIH National Institute of Diabetes and Digestive and Kidney Diseases. The main study looked at how a high sugar diet in the mother turns genes on and off in the developing offspring.
It compared them with mothers fed a low sugar diet, replacing sugar with a mix of sucralose and acesulfame-K (AK), two non-nutrient artificial sugars that are already used extensively in our food products and thought to be safe.
While the artificial sweeteners had little effect on the mothers, the trace amounts that were transferred through the placenta and milk had a profound effect on the pups. Hanover believes the molecules are changing gene expression during a crucial, short period of development.
"Somewhat to our surprise, we saw in the pups a really dramatic change in the microbiome" of those whose mothers were fed the artificial sweeteners, Hanover told leapsmag. "It looked like the neonates were much, much more sensitive than their mothers to the sucralose and AK." The unexpected discovery led them to publish a separate paper.
"The protective microbe Akkermansia was largely missing, and we saw a pretty dramatic shift in the ratio of two bacteria that are normally associated with metabolic disease," a precursor to diabetes, he explains. Akkermansia is a bacteria that feeds on mucus in the gut and helps remodel the tissue to an adult state over the first several months of life in a mouse. A similar process takes several years in humans, as the infant is weaned off of breast milk as the primary food source.
The good news is the body seems to remove these artificial sweeteners fairly quickly, probably within a week.
Another problem the researchers saw in the animals was "a particularly striking change in the metabolism of the detoxification systems" in the liver, says Hanover. A healthy liver is dark red, but a high dose of the artificial sweeteners turned it white, "which is a sign of massive problems."
The study was conducted in mice and Hanover cautions the findings may not apply to humans. "But in general, the microbiome changes that one sees in the rodent model mimics what we see in humans...[and] the genes that are turned on in the mouse and the human are very similar."
Hanover acknowledges the quantity of artificial sweeteners used in the study is on the high end of human consumption, roughly the equivalent of 20 cans of diet soda a day. But the sweeteners are so ubiquitous in consumer products, from foods to lipstick, and often not even mentioned on the label, that it is difficult to measure just how much a person consumes every day.
The good news is the body seems to remove these artificial sweeteners fairly quickly, probably within a week. Until further studies provide a clearer picture, women who want to err on the side of caution can choose to reduce if not eliminate their exposure to artificial sweeteners during pregnancy and breastfeeding.
NASA Has the Technology to Save Us From an Asteroid Strike, But Congress Won’t Fund It
If a massive asteroid were to strike the Earth, it could be more destructive than a thousand atomic bombs.
At the biannual Planetary Defense Conference earlier this year, NASA ran a simulation of an asteroid slamming into the center of Manhattan.
For several millennia now, we've been lucky, but our luck won't hold out forever.
The gathering of astronomers, planetary scientists, and FEMA disaster-response experts attempted a number of interventions that might be possible within a time window of eight years, the given warning period before impact.
Catastrophic asteroid crashes are not without precedent, and scientists say it's only a matter of time before another one occurs—that is, if we do nothing to prevent it. It's believed that a huge asteroid crash off the coast of Mexico's Yucatan Peninsula created a worldwide disaster that helped to speed the extinction of the dinosaurs 65 million years ago.
In 1908, a meteoroid less than 300 feet in diameter exploded in the air over the Tunguska region of Siberia, creating a shockwave that leveled trees for hundreds of square miles. It's a matter of sheer luck it didn't hit a major population center, where human casualties could have been enormous.
For several millennia now, we've been lucky, but our luck won't hold out forever. There are millions of asteroids circulating about in our solar system, some of them hundreds of miles across, and although the odds of a massive one crashing to Earth in the near future is statistically low, the devastation could be apocalyptic.
Back at the conference, the experts tried sending several spacecrafts to knock the asteroid off-course by slamming into it. They considered blasting it with nuclear weapons. They even considered painting it white so it absorbed less of the sun's energy, hoping that would shift the asteroid's trajectory. In the simulations, all of the interventions failed and the giant space rock crashed into Manhattan, killing 1.3 million people in a massive explosion that was 1,000 times more powerful than the Hiroshima bomb.
NEOCam is designed, tested, and ready to build, but the project is currently frozen because of a $40 million gap in NASA funding.
Given more time, the scientists said, they might have succeeded in preventing the disaster. However, with today's asteroid-hunting telescopes, it's not likely we would have more warning. Our current telescopes are not powerful enough to detect all the near-earth asteroids, nor are they positioned well enough for sufficient detection. As recently as last week, for example, an asteroid traveling 15 miles a second narrowly missed crashing into the Earth, and it was only noticed several days in advance.
Now for the good news: There is a new technology that could buy us the time we need, says MIT planetary sciences professor Richard P. Binzel and colleagues who attended the conference. The Near-Earth Object Camera, or NEOCam, designed by NASA's Jet Propulsion Laboratory, would detect more than 90 percent of nearby objects that are 420 feet across or larger, according to Binzel.
The powerful infrared telescope is designed to sit within the L1 Lagrange point, a stable location in space where the gravitational pulls of the Earth and the sun cancel each other out. From there, large space bodies could be detected early enough to give scientists decades of warning when an asteroid is heading for Earth. NEOCam is designed, tested, and ready to build, but the project is currently frozen because of a $40 million gap in NASA funding.
The status of NEOCam, according to Binzel, is a case-study in short-sightedness and a lack of leadership. Congress needs to raise NASA's Planetary Defense budget from its current $160 million to $200 million to get the telescope built and launched into space, a goal that would seem eminently doable within the strictures of 2020's $4.75 trillion government budget. But Binzel describes a current deadlock between NASA, Congress, and the Office of Management and Budget as a "cosmic game of chicken."
If we don't use our technology to defend the planet, "it would be the most epic failure in the history of science."
In an excruciatingly budget-conscious atmosphere, "No one wants to stick their neck out and take adult responsibility" for getting the funding allocated that would unfreeze the project, says Binzel. But, he adds, "We have a moral obligation to act."
NEOCam would not only spot the overwhelming majority of asteroids in Earth's vicinity, it would determine their size and pinpoint exactly where they are likely to strike the Earth. And it would allow us decades to act, according to Binzel. Repeated ramming by an international armada of specialized spacecraft could slightly change the trajectory of an asteroid, he says. Changing the trajectory only a tiny bit, given the scale of millions of miles and several decades for the course change to take effect, could cause an asteroid to miss the Earth altogether.
"So far we've been relying on luck," says Binzel, "but luck is not a plan." Now that we have the technology to discover what's careening through our space neighborhood, it's our ethical duty to deploy it. If we don't use our technology to gain the knowledge we need to defend the planet, Binzel concludes, "it would be the most epic failure in the history of science."
Should Congress green light the $40 million budget for the new asteroid-hunting telescope? @NASA #NASA #astroid— leapsmag (@leapsmag) 1564681293.0