This post is a part of our Bioethics in the News series
By Sabrina Ford, PhD
Technology. It invades every corner of our lives and for the most part improves the quality of life. From typing on a flat panel with a little TV screen attached, to a smartphone enabling users to share with others collected data that lives in the cloud. A CT/X-ray image of a C2 spinal fracture (aka Hangman’s Fracture) taken in the middle of the night at a small Midwestern rural hospital is sent to a West Coast spine surgeon, and within minutes, an expert opinion is returned to that rural hospital. Technology is convenient, pervasive, and unavoidable.
In the past 15 years, discussion and related controversy has taken place about a Radio Frequency Identification Device (RFID) or microchip that can be implanted in human bodies. That chip would contain, store, and update data about us. Might such an implant be a benefit or a risk? Some investors are betting on its appeal. The compound annual growth rate (CAGR) from 2020-2027 of the healthcare microchip is expected to grow by 22% and be valued over $6.4 million by 2027. RFID microchips (herein referred to as microchips) are already used for many things from your credit/debit card, to those efficient logistics used to move your Amazon package.
Getting to the bridge
Implanted microchips are a terrifying idea to some of us—sufficiently frightening to harken images of robots and androids—the stuff of science fiction. For some of us, implanting something foreign in our bodies for the management of big data and convenience is disturbing. Another concern might be the potential breach of privacy and the surveillance of our daily life. If the chip contains medical, personal, social information, and GPS data, could we lose all autonomy? Do we maintain our autonomy if, with sufficient information, we consent to the decision? What will all the information be used or misused for? What if our employer, insurer, or a government entity decides to check on us?
These questions raise other concerns about autonomy. Enough employers considered compulsory microchips for their employees that in 2020, Michigan and several other states introduced and passed bills designed to prevent employers from forcing employees to accept microchip implants. This pre-emptive strike was against a growing technology, utilized perhaps to track safety, productivity and movement. As with many things in the United States, some vulnerable employees with microchips might be targeted, either unintentionally or intentionally, thereby putting them at further economic and social disadvantage.
Some have already crossed the bridge
It is estimated that currently approximately 10,000 people in the world have implanted microchips. Perhaps that doesn’t sound like many, but if investors are hedging their bets correctly, the technology is on its way to widespread adoption. A large number of those “cyborgs” reside in Sweden and employ the technology not for health care reasons, but instead use microchip implants to unlock their car doors, buy a coffee, or swipe into the gym. That rate of chip adoption makes sense in a society like Sweden, which is the second most cashless society (after Canada) in the world.
Many argue that an RFID tag and implanted microchips can increase cybersecurity. Not being able to log into your computer without first swiping into the building and into your office door might offer a level of comforting protection against physical hacking in the workplace. In addition, many in healthcare delivery believe medical mistakes would be greatly reduced and quality of care increased if our medical charts were loaded on microchips, monitoring disease states like heart disease and diabetes, improving management of medications, and reducing surgical mistakes. If, with microchips, first responders or doctors had real-time access to accurate medical information there is potential to save lives in medical emergencies. The HITECH Act—or Health Information Technology for Economic and Clinical Health Act—calls for the interoperability of electronic health information for privacy and safety of the patient. As it is now, it doesn’t make sense for an individual to have different electronic health records in a number of physician offices. If our world were to be efficiently hyperconnected, one can argue that everyday life could be improved and streamlined.
A bridge too far
But would it be? We are covered, watched, followed, and violated through our digital footprint on a daily basis. Perhaps not necessarily with microchips, but pause to consider your actions today. You took your morning walk as public cameras captured your movement down the block, into the convenience store for a cup of coffee, where you used your debit card or smartphone to pay for the transaction, and that transaction was caught on the store camera. You then check your fitness wearable for heart rate, steps, route, and all that other good stuff. Later, you swipe in and out of the building as you stop into your office for a few hours, in and out of several doors, and log on to your computer—accessing various applications in the cloud—all the while answering your email and checking your calendar. Later in the day, you visit your doctor, either in person or via telemedicine, and she enters your ailments, diagnostic tests ordered, and electronic prescriptions into the electronic health record. As you wind down for the evening you make your market list in your favorite grocery store app, use your smart television to access your favorite shows, and access your books on a reading app. All of this is accomplished in the cloud, and on the “grid” in huge databases. Is this trek through the digital world so much different than a microchip that holds your digital footprint? You’ve left a day’s breadcrumb trail on almost every aspect of your life, and not even as consciously as Hansel and Gretel. As for implants in general, clearly Americans accept them, as witnessed by artificial joints, IUDs, cochlear implants – and don’t forget about those implants for hair and breasts.
Over the bridge
The described dilemma is that implanting a chip has the potential to be a violation of rights, yet the chip might equally offer safety and convenience. The implantable microchip is not fully developed and has a long way to go, but the technology is on its way. Microchips today are not sufficiently powerful to collect and communicate big data or to follow us all over the world the way our smartphones do. As with most technologies, the tipping point for implantable chips will come when they become so very useful that they’re simply hard to refuse.
Sabrina Ford, PhD, is an Associate Professor in the Department of Obstetrics, Gynecology and Reproductive Biology and the Institute for Health Policy in the Michigan State University College of Human Medicine. Dr. Ford is also adjunct faculty with the Center for Ethics and Humanities in the Life Sciences.
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- Acumen Research and Consulting. Radio Frequency Identification (RFID) in healthcare market–global industry analysis, market size, opportunities and forecast, 2020-2027. GlobeWire, Los Angeles, Feb. 17, 2021. Accessed 17 Feb 2021: http://www.globenewswire.com/news-release/2021/02/17/2177335/0/en/Radio-Frequency-Identification-RFID-In-Healthcare-Market-Value-Anticipated-To-Reach-US-6-435-7-Million-By-2027-Acumen-Research-And-Consulting.html
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- Michigan House Bill 5672. Accessed 18 Feb 2021. https://www.legislature.mi.gov/documents/2019-2020/billintroduced/House/pdf/2020-HIB-5672.pdf
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- Hawrylak PJ, Hale J. Data Privacy Issues with RFID in Healthcare. In: Gkoulalas-Divanis A., Loukides G. (eds), 2015, Medical Data Privacy Handbook. Springer, Cham. https://doi.org/10.1007/978-3-319-23633-9_21; https://link.springer.com/chapter/10.1007/978-3-319-23633-9_21