“Coming Back from the Dead” Is No Longer Science Fiction
Last year, there were widespread reports of a 53-year-old Frenchman who had suffered a cardiac arrest and "died," but was then resuscitated back to life 18 hours after his heart had stopped.
The once black-and-white line between life and death is now blurrier than ever.
This was thought to have been possible in part because his body had progressively cooled down naturally after his heart had stopped, through exposure to the outside cold. The medical team who revived him were reported as being "stupefied" that they had been able to bring him back to life, in particular since he had not even suffered brain damage.
Interestingly, this man represents one of a growing number of extraordinary cases in which people who would otherwise be declared dead have now been revived. It is a testament to the incredible impact of resuscitation science -- a science that is providing opportunities to literally reverse death, and in doing so, shedding light on the age-old question of what happens when we die.
Death: Past and Present
Throughout history, the boundary between life and death was marked by the moment a person's heart stopped, breathing ceased, and brain function shut down. A person became motionless, lifeless, and was deemed irreversibly dead. This is because once the heart stops beating, blood flow stops and oxygen is cut off from all the body's organs, including the brain. Consequently, within seconds, breathing stops and brain activity comes to a halt. Since the cessation of the heart literally occurs in a "moment," the philosophical notion of a specific point in time of "irreversible" death still pervades society today. The law, for example, relies on "time of death," which corresponds to when the heart stops beating.
The advent of cardiopulmonary resuscitation (CPR) in the 1960s was revolutionary, demonstrating that the heart could potentially be restarted after it had stopped, and what had been a clear black-and-white line was shown to be potentially reversible in some people. What was once called death—the ultimate end point— was now widely called cardiac arrest, and became a starting point.
From then on, it was only if somebody had requested not to be resuscitated or when CPR was deemed to have failed that people would be declared dead by "cardiopulmonary criteria." Biologically, cardiac arrest and death by cardiopulmonary criteria are the same process, albeit marked at different points in time depending on when a declaration of death is made.
The apparent irreversibility of death as we know it may not necessarily reflect true irretrievable cellular damage inside the body.
Clearly, contrary to many people's perceptions, cardiac arrest is not a heart attack; it is the final step in death irrespective of cause, whether it be a stroke, a heart attack, a car accident, an overwhelming infection or cancer. This is how roughly 95 percent of the population are declared dead.
The only exception is the small proportion of people who may have suffered catastrophic brain injuries, but whose hearts can be artificially kept beating for a period of time on life-support machines. These people can be legally declared dead based on brain death criteria before their hearts have stopped. This is because the brain can die either from oxygen starvation after cardiac arrest or from massive trauma and internal bleeding. Either way, the brain dies hours or possibly longer after these injuries have taken place and not just minutes.
A Profound Realization
What has become increasingly clear is that the apparent irreversibility of death as we know it may not necessarily reflect true irretrievable cellular damage inside the body. This is consistent with a mounting understanding: it is only after a person actually dies that the cells in the body start to undergo their own process of death. Intriguingly, this process is something that can now be manipulated through medical intervention. Being cold is one of the factors that slows down the rate of cellular decay. The 53-year-old Frenchman's case and the other recent cases of resuscitation after prolonged periods of time illustrate this new understanding.
Last week's earth-shattering announcement by neuroscientist Dr. Nenad Sestan and his team out of Yale, published in the prestigious scientific journal Nature, provides further evidence that a time gap exists between actual death and cellular death in cadavers. In this seminal study, these researchers were able to restore partial function in pig brains four hours after their heads were severed from their bodies. These results follow from the pioneering work in 2001 of geneticist Fred Gage and colleagues from the Salk Institute, also published in Nature, which demonstrated the possibility of growing human brain cells in the laboratory by taking brain biopsies from cadavers in the mortuary up to 21 hours post-mortem.
The once black-and-white line between life and death is now blurrier than ever. Some people may argue this means these humans and pigs weren't truly "dead." However, that is like saying the people who were guillotined during the French Revolution were also not dead. Clearly, that is not the case. They were all dead. The problem is not death; it's our reliance on an outdated philosophical, rather than biological, notion of death.
Death can no longer be considered an absolute moment but rather a process that can be reversed even many hours after it has taken place.
But the distinction between irreversibility from a medical perspective and biological irreversibility may not matter much from a pragmatic perspective today. If medical interventions do not exist at any given time or place, then of course death cannot be reversed.
However, it is crucial to distinguish between biologically and medically: When "irreversible" loss of function arises due to inadequate treatment, then a person could be potentially brought back in the future when an alternative therapy becomes available, or even today if he or she dies in a location where novel treatments can slow down the rate of cell death. However, when true irreversible loss of function arises from a biological perspective, then no treatment will ever be able to reverse the process, whether today, tomorrow, or in a hundred years.
Probing the "Grey Zone"
Today, thanks to modern resuscitation science, death can no longer be considered an absolute moment but rather a process that can be reversed even many hours after it has taken place. How many hours? We don't really know.
One of the wider implications of our medical advances is that we can now study what happens to the human mind and consciousness after people enter the "grey zone," which marks the time after the heart stops, but before irreversible and irretrievable cell damage occurs, and people are then brought back to life. Millions have been successfully revived and many have reported experiencing a unique, universal, and transformative mental state.
Were they "dead"? Yes, according to all the criteria we have ever used. But they were able to be brought back before their "dead" bodies had reached the point of permanent, irreversible cellular damage. This reflects the period of death for all of us. So rather than a "near-death experience," I prefer a new terminology to describe these cases -- "an actual-death experience." These survivors' unique experiences are providing eyewitness testimonies of what we will all be likely to experience when we die.
Such an experience reportedly includes seeing a warm light, the presence of a compassionate perfect individual, deceased relatives, a review of their lives, a judgment of their actions and intentions as they pertain to their humanity, and in some cases a sensation of seeing doctors and nurses working to resuscitate them.
Are these experiences compatible with hallucinations or illusions? No -- in part, because these people have described real, verifiable events, which, by definition are not hallucinations, and in part, because their experiences are not compatible with confused and delirious memories that characterize oxygen deprivation.
The challenge for us scientifically is understanding how this is possible at a time when all our science tells us the brain shuts down.
For instance, it is hard to classify a structured meaningful review of one's life and one's humanity as hallucinatory or illusory. Instead, these experiences represent a new understanding of the overall human experience of death. As an intensive care unit physician for more than 10 years, I have seen numerous cases where these reports have been corroborated by my colleagues. In short, these survivors have been known to come back with reports of full consciousness, with lucid, well-structured thought processes and memory formation.
The challenge for us scientifically is understanding how this is possible at a time when all our science tells us the brain shuts down. The fact that these experiences occur is a paradox and suggests the undiscovered entity we call the "self," "consciousness," or "psyche" – the thing that makes us who we are - may not become annihilated at the point of so-called death.
At New York University, the State University of New York, and across 20 hospitals in the U.S. and Europe, we have brought together a new multi-disciplinary team of experts across many specialties, including neurology, cardiology, and intensive care. Together, we hope to improve cardiac arrest prevention and treatment, as well as to address the impact of new scientific discoveries on our understanding of what happens at death.
One of our first studies, Awareness during Resuscitation (AWARE), published in the medical journal Resuscitation in 2014, confirmed that some cardiac arrest patients report a perception of awareness without recall; others report detailed memories and experiences; and a few report full auditory and visual awareness and consciousness of their experience, from a time when brain function would be expected to have ceased.
While you probably have some opinion or belief about this based upon your own philosophical, religious, or cultural background, you may not realize that exploring what happens when we die is now a subject that science is beginning to investigate.
There is no question more intriguing to humankind. And for the first time in our history, we may finally uncover some real answers.
Trying to get a handle on CRISPR news in 2019 can be daunting if you haven't been avidly reading up on it for the last five years.
CRISPR as a diagnostic tool would be a major game changer for medicine and agriculture.
On top of trying to grasp how the science works, and keeping track of its ever expanding applications, you may also have seen coverage of an ongoing legal battle about who owns the intellectual property behind the gene-editing technology CRISPR-Cas9. And then there's the infamous controversy surrounding a scientist who claimed to have used the tool to edit the genomes of two babies in China last year.
But gene editing is not the only application of CRISPR-based biotechnologies. In the future, it may also be used as a tool to diagnose infectious diseases, which could be a major game changer for medicine and agriculture.
How It Works
CRISPR is an acronym for a naturally occurring DNA sequence that normally protects microbes from viruses. It's been compared to a Swiss army knife that can recognize an invader's DNA and precisely destroy it. Repurposed for humans, CRISPR can be paired with a protein called Cas9 that can detect a person's own DNA sequence (usually a problematic one), cut it out, and replace it with a different sequence. Used this way, CRISPR-Cas9 has become a valuable gene-editing tool that is currently being tested to treat numerous genetic diseases, from cancer to blood disorders to blindness.
CRISPR can also be paired with other proteins, like Cas13, which target RNA, the single-stranded twin of DNA that viruses rely on to infect their hosts and cause disease. In a future clinical setting, CRISPR-Cas13 might be used to diagnose whether you have the flu by cutting a target RNA sequence from the virus. That spliced sequence could stick to a paper test strip, causing a band to show up, like on a pregnancy test strip. If the influenza virus and its RNA are not present, no band would show up.
To understand how close to reality this diagnostic scenario is right now, leapsmag chatted with CRISPR pioneer Dr. Feng Zhang, a molecular biologist at the Broad Institute of MIT and Harvard.
What do you think might be the first point of contact that a regular person or patient would have with a CRISPR diagnostic tool?
FZ: I think in the long run it will be great to see this for, say, at-home disease testing, for influenza and other sorts of important public health [concerns]. To be able to get a readout at home, people can potentially quarantine themselves rather than traveling to a hospital and then carrying the risk of spreading that disease to other people as they get to the clinic.
"You could conceivably get a readout during the same office visit, and then the doctor will be able to prescribe the right treatment right away."
Is this just something that people will use at home, or do you also foresee clinical labs at hospitals applying CRISPR-Cas13 to samples that come through?
FZ: I think we'll see applications in both settings, and I think there are advantages to both. One of the nice things about SHERLOCK [a playful acronym for CRISPR-Cas13's longer name, Specific High-sensitivity Enzymatic Reporter unLOCKing] is that it's rapid; you can get a readout fairly quickly. So, right now, what people do in hospitals is they will collect your sample and then they'll send it out to a clinical testing lab, so you wouldn't get a result back until many hours if not several days later. With SHERLOCK, you could conceivably get a readout during the same office visit, and then the doctor will be able to prescribe the right treatment right away.
I just want to clarify that when you say a doctor would take a sample, that's referring to urine, blood, or saliva, correct?
FZ: Right. Yeah, exactly.
Thinking more long term, are there any Holy Grail applications that you hope CRISPR reaches as a diagnostic tool?
FZ: I think in the developed world we'll hopefully see this being used for influenza testing, and many other viral and pathogen-based diseases—both at home and also in the hospital—but I think the even more exciting direction is that this could be used and deployed in parts of the developing world where there isn't a fancy laboratory with elaborate instrumentation. SHERLOCK is relatively inexpensive to develop, and you can turn it into a paper strip test.
Can you quantify what you mean by relatively inexpensive? What range of prices are we talking about here?
FZ: So without accounting for economies of scale, we estimate that it can cost less than a dollar per test. With economy of scale that cost can go even lower.
Is there value in developing what is actually quite an innovative tool in a way that visually doesn't seem innovative because it's reminiscent of a pregnancy test? And I don't mean that as an insult.
FZ: [Laughs] Ultimately, we want the technology to be as accessible as possible, and pregnancy test strips have such a convenient and easy-to-use form. I think modeling after something that people are already familiar with and just changing what's under the hood makes a lot of sense.
Feng Zhang
(Photo credit: Justin Knight, McGovern Institute)
It's probably one of the most accessible at-home diagnostic tools at this point that people are familiar with.
FZ: Yeah, so if people know how to use that, then using something that's very similar to it should make the option very easy.
You've been quite vocal in calling for some pauses in CRISPR-Cas9 research to make sure it doesn't outpace the ethics of establishing pregnancies with that version of the tool. Do you have any concerns about using CRISPR-Cas13 as a diagnostic tool?
I think overall, the reception for CRISPR-based diagnostics has been overwhelmingly positive. People are very excited about the prospect of using this—for human health and also in agriculture [for] detection of plant infections and plant pathogens, so that farmers will be able to react quickly to infection in the field. If we're looking at contamination of foods by certain bacteria, [food safety] would also be a really exciting application.
Do you feel like the controversies surrounding using CRISPR as a gene-editing tool have overshadowed its potential as a diagnostics tool?
FZ: I don't think so. I think the potential for using CRISPR-Cas9 or CRISPR-Cas12 for gene therapy, and treating disease, has captured people's imaginations, but at the same time, every time I talk with someone about the ability to use CRISPR-Cas13 as a diagnostic tool, people are equally excited. Especially when people see the very simple paper strip that we developed for detecting diseases.
Are CRISPR as a gene-editing tool and CRISPR as a diagnostics tool on different timelines, as far as when the general public might encounter them in their real lives?
FZ: I think they are all moving forward quite quickly. CRISPR as a gene-editing tool is already being deployed in human health and agriculture. We've already seen the approval for the development of growing genome-edited mushrooms, soybeans, and other crop species. So I think people will encounter those in their daily lives in that manner.
Then, of course, for disease treatment, that's progressing rapidly as well. For patients who are affected by sickle cell disease, and also by a degenerative eye disease, clinical trials are already starting in those two areas. Diagnostic tests are also developing quickly, and I think in the coming couple of years, we'll begin to see some of these reaching into the public realm.
"There are probably 7,000 genetic diseases identified today, and most of them don't have any way of being treated."
As far its limits, will it be hard to use CRISPR as a diagnostic tool in situations where we don't necessarily understand the biological underpinnings of a disease?
FZ: CRISPR-Cas13, as a diagnostic tool, at least in the current way that it's implemented, is a detection tool—it's not a discovery tool. So if we don't know what we're looking for, then it's going to be hard to develop Cas13 to detect it. But even in the case of a new infectious disease, if DNA sequencing or RNA sequencing information is available for that new virus, then we can very rapidly program a Cas13-based system to detect it, based on that sequence.
What's something you think the public misunderstands about CRISPR, either in general, or specifically as a diagnostic tool, that you wish were better understood?
FZ: That's a good question. CRISPR-Cas9 and CRISPR-Cas12 as gene editing tools, and also CRISPR-Cas13 as a diagnostic tool, are able to do some things, but there are still a lot of capabilities that need to be further developed. So I think the potential for the technology will unfold over the next decade or so, but it will take some time for the full impact of the technology to really get realized in real life.
What do you think that full impact is?
FZ: There are probably 7,000 genetic diseases identified today, and most of them don't have any way of being treated. It will take some time for CRISPR-Cas9 and Cas12 to be really developed for addressing a larger number of those diseases. And then for CRISPR-based diagnostics, I think you'll see the technology being applied in a couple of initial cases, and it will take some time to develop that more broadly for many other applications.
Researchers Are Experimenting With Magic Mushrooms' Fascinating Ability to Improve Mental Health Disorders
Mental illness is a dark undercurrent in the lives of tens of millions of Americans. According to the World Health Organization, about 450 million people worldwide have a mental health disorder, which cut across all demographics, cultures, and socioeconomic classes.
One area of research seems to herald the first major breakthrough in decades — hallucinogen-assisted psychotherapy.
The U.S. National Institute on Mental Health estimates that severely debilitating mental health disorders cost the U.S. more than $300 billion per year, and that's not even counting the human toll of broken lives, devastated families, and a health care system stretched to the limit.
However, one area of research seems to herald the first major breakthrough in decades — hallucinogen-assisted psychotherapy. Drugs like psilocybin (obtained from "magic mushrooms"), LSD, and MDMA (known as the club drug, ecstasy) are being tested in combination with talk therapy for a variety of mental illnesses. These drugs, administered by a psychotherapist in a safe and controlled environment, are showing extraordinary results that other conventional treatments would take years to accomplish.
But the therapy will likely continue to face an uphill legal battle before it achieves FDA approval. It is up against not only current drug laws (all psychedelics remain illegal on the federal level) and strict FDA regulations, but a powerful status quo that has institutionalized fear of any drug used for recreational purposes.
How We Got Here
According to researchers Sean Belouin and Jack Henningfield, the use of psychedelic drugs has a long and winding history. It's believed that hallucinogenic substances have been used in healing ceremonies and religious rituals for thousands of years. Indigenous people in the U.S., Mexico, and Central and South America still use distillations from the peyote cactus and other hallucinogens in their religious ceremonies. And psilocybin mushrooms, also capable of causing hallucinations, grow throughout the world and are thought to have been used for millennia.
But psychedelic drugs didn't receive much research until 1943, when LSD's psychoactive effects were discovered by chemist Albert Hoffman. Hoffman tested the compound he had discovered years earlier on himself and found that the drug had profound mind-altering effects. He made the drug available to psychiatrists who were interested in testing it out as an adjunct to talk therapy. There were no truly effective drugs at the time for mental illnesses, and psychiatrists early on saw the possibility of psychedelics providing a kind of emotional catharsis that might represent therapeutic breakthroughs for many mental conditions.
During the 1950s and early 1960s, psychedelic drugs saw an increase in use within psychology, according to a 2018 article in Neuropharmacology. During this time, research on LSD and other hallucinogens was the subject of over 1,000 scientific papers, six international conferences, and several dozen books. LSD was widely prescribed to psychiatric patients, and by 1958, Hoffman had identified psilocybin as the hallucinogenic in "magic mushrooms," which was also administered. By 1965 some type of hallucinogenic had been given to more than 40,000 patients.
Then came a sea change. Psychedelic drugs caught the public's attention and there was widespread experimentation. The association with Hippie counterculture alarmed many and led to a legal and cultural backlash that stigmatized psychedelics for decades to come. In the mid-1960s, psychedelics were designated Schedule 1 drugs in the U.S., meaning they were seen as having "no accepted medical use and a high potential of abuse." Schedule 1 also implied that the drugs were more dangerous than cocaine, methamphetamine, Vicodin, and oxycodone, a perception that was far from proven but became an institutionalized part of drug enforcement. Medical use ceased and research dwindled down to close to zero.
For years, research into hallucinogenic-assisted therapy was basically dormant, until the 1990s when interest started to revive. In the 2000s, the first modern clinical trials of psilocybin were done by Francisco Moreno at the University of Arizona and Matthew Johnson at Johns Hopkins. Scientists in the 2010s, including Robin Carhart-Harris, started studying the use of psychedelics in the treatment of major depressive disorder (MDD).
In small trials with these patients, results showed significant and long-term improvement (for at least six months) after only two episodes of psilocybin-assisted therapy. In several studies, the guided experience of administering one of the psychedelic drugs along with psychotherapy seemed to result in marked improvement in a variety of disorders, including depression, anxiety, PTSD, and addiction.
The drugs allowed patients to experience a radical reframing of reality, helping them to become "unstuck" from the anxious and negative tape loops that played in their heads. According to Michael Pollan, an American author and professor of journalism who wrote the book, "How to Change Your Mind: What the New Science of Psychedelics Teaches Us About Consciousness, Dying, Addiction, Depression and Transcendence," psychedelics allow patients to see their lives through a kind of wide angle, where boundaries vanish and they're able to experience "consciousness without self." This perspective is usually accompanied by profound feelings of oneness with the universe.
Pollan likens the effect to a fresh blanketing of snow over the deep ruts of unproductive thinking, which characterize depression and other mental disorders. Once the new snow has fallen, the ruts disappear and a new path can be chosen. Relief from symptoms comes immediately, and in numerous studies, is sustained for months.
In spite of growing evidence for the safety and efficacy of psychedelic-assisted psychotherapy, the practice has major hurdles to cross on its quest for FDA approval.
Some of the most influential studies have focused on testing the use of psilocybin to treat end-of-life anxiety in patients diagnosed with a terminal illness. In 2016, Stephen Ross and colleagues tested a single dose of psilocybin on 29 subjects with end-of-life anxiety due to a terminal cancer diagnosis. A control group received a niacin pill. The researchers reported that of the 29 receiving psilocybin, all of the patients had "immediate, substantial, and sustained clinical benefits," even after six months.
In spite of growing evidence for the safety and efficacy of psychedelic-assisted psychotherapy, the practice has major hurdles to cross on its quest for FDA approval. The National Institutes of Health is not currently supporting any clinical trials and the research relies on private sources of funding, often with small research organizations that cannot afford the high cost of clinical trials.
Given the controversial nature of the drugs, researchers in psychedelic-assisted therapies may be cautious about publicity. Leapsmag reached out to several leaders in the field but none agreed to an interview.
Looking Ahead
Still, interest is building in the combination of psychedelic drugs and psychotherapy for treatment-resistant mental illnesses. Two months ago, Johns Hopkins University launched a new psychedelic research center with an infusion of $17 million from private investors. The center will focus on psychedelic-assisted therapies for opioid addiction, Alzheimer's disease, PTSD and major depression, to name just a few. Currently, of 51 cancer patients enrolled in a Hopkins study, more than half reported a decrease in depression and anxiety after receiving therapy with psilocybin. Two thirds even claimed that the experience was one of the most meaningful of their lives.
It is not unheard of for Schedule 1 drugs to make their way into medical use if they're shown to provide a bonafide improvement in a medical condition through well-designed clinical trials. MDMA, for example, has been designated a Breakthrough Therapy by the FDA as part of an Investigational New Drug Application. The FDA has agreed to a special protocol assessment that could speed up phase three clinical trials. The next step is for the data to be submitted to the FDA for an in-depth regulatory review. If the FDA agrees, MDMA-assisted therapy could be legalized.
Will the positive buzz around psychedelics persuade the NIH to provide the millions of dollars needed to push the field forward?
Robin Carhart-Harris believes the first drug that will receive FDA clearance is psilocybin, which he speculates could become legal in the next five to ten years. However, the field of psychedelic-assisted therapy needs more and larger clinical trials, preferably with the support of the NIH.
As Rucker and colleagues noted, the scientific literature bends toward the theme that the drugs are not necessarily therapeutic in and of themselves. It's the use of hallucinogens within a "psychologically supportive context" with a trained expert that's helpful. It's currently unknown how many users of recreational drugs are self-medicating for depression, anxiety, or other mental illnesses. But without the guidance of a knowledgeable psychotherapist, those who are self-medicating may not be helping themselves at all.
Will the positive buzz around psychedelics persuade the NIH to provide the millions of dollars needed to push the field forward? Given the changing climate in public opinion around these drugs and the need for breakthroughs in mental health therapies, it's possible that in the foreseeable future, this bold new therapy will become part of the mental health arsenal.