David Shaywitz

Peter Attia is a prominent physician-turned-California longevity guru, and (to paraphrase Woody Allen) as California longevity gurus go, he’s one of the best, striving to remain grounded in science and data.

Known for his popular book Outlive, and his affection for “rucking” (look it up), Attia is also the host of a long-form podcast called The Drive, and an engaging guest on other worthwhile podcasts including Patrick O’Shaughnessy’s “Invest Like the Best” (here) and Bari Weiss’s “Honestly” (here).  He’s also the founder of Early, which describes itself as a science-based health program to “build your own, personalized, end-to-end longevity playbook.”

Attia’s latest podcast features a lengthy (two hour), exceptionally illuminating interview about AI and medicine with Zak Kohane, a physician-scientist at Harvard Medical School and head of the Department of Biomedical Informatics (with which I’m affiliated). 

The discussion starts with a quick, knowledgeable review of the history of AI (interested readers might also enjoy several of the books summarized here), and then explores how AI is likely to impact health and medicine.

Peter Attia

The entire episode – with thoughtful questions from Attia and nuanced replies from Kohane – is unquestionably worth the time (and extra credit if, like me, you listen while jogging, even if not quite rucking). 

However, I wanted to highlight three related topics raised by these two senior medical experts that were especially striking:

• How AI may fit into the evolution of medicine (tl;dr AI augmentation of non-MD health providers, initially in domains where there aren’t enough doctors);
• What’s most likely to keep the promise of AI in health from being fully realized (tl;dr incumbent healthcare systems maintaining their stranglehold on patient data)
• What’s the most promising driver of AI-enabled disruption in medicine (tl;dr empowered, exceptionally motivated patients and their families)

AI and the future of medicine

AI is already poised to impact medicine. Kohane highlights the promise of AI in image-based specialties such as dermatology and radiology, where high-resolution images, fed into machine learning models, can identify image abnormalities as well as (and in many cases even better than) the human eye. 

He also points out that in contrast to the infamous prediction of legendary AI expert Geoff Hinton (who suggested in 2016 that radiologists would be obsolete in 5-10 years), AI’s “are not replacing the doctors because image recognition process is only part of their job.” 

Focusing on the use of AI for physician augmentation (rather than replacement), Attia suggests the adoption of AI would likely occur in two stages.  The first specialties to be impacted, he says, will probably be those he describes as visually focused: pathology, radiology, dermatology, and cardiology (especially those most involved in interpreting cardiac imaging studies).  Next would be specialties he sees as focused on integrating “language data” and visual data, like primary care doctors and pediatricians.

Zak Kohane, Chair of the Department of Biomedical Informatics, Harvard Medical School

While Kohane says he agreed with Attia’s proposed order of adoption, he emphasizes that a more immediate consideration is the shortage of doctors in key areas like primary care. 

“You have to ask yourself, how can we replace these absent primary care practitioners with nurse practitioners, with physician assistants augmented by these AIs, because there’s literally no doctor to replace.”

More broadly, medicine’s challenge and AI’s opportunity, as Kohane describes it, is that fewer doctors are choosing to go into specialties not associated with highly financially remunerative procedures.  While there doesn’t appear to be a shortage of future interventional radiologists or dermatologists (which he describes as high-paying and high prestige), there aren’t enough traditional radiologists or primary care doctors. 

“I go around medical schools and ask who’s becoming a primary care doctor?  Almost nobody,” Kohane said.  “So primary care is disappearing in the United States. In fact, Mass General and Brigham announced officially they’re not seeing [new] primary care patients [see here].”

Kohane continues,

“There’s a huge gap emerging in the available expertise. So, it’s not what we thought it was going to be, that we had a surplus of doctors that had to be replaced [by AI]. It’s just we have a surplus in a few focused areas which are very popular. And then for all the work of primary care and primary prevention kind of stuff that you [i.e. Peter Attia] are interested in, we have almost no doctors available.”

The gap in “expert clinicians,” Kohane suggests, might be filled by non-MDs like nurse practitioners and physician-assistants augmented by AI.

Impediment to AI-Innovation in Healthcare

The tremendous potential of AI today, Kohane explains, can be attributed to the compounding effects of large data sets, neural networks, and suitable computer chips (GPUs). 

Kohane describes the tremendous importance of rich clinical datasets, the sort of information one might associate with electronic health records (EHRs). 

However, he notes that the EHR “turns out not to be the answer in the United States. Why? Because in the United States, we move around. We don’t stay in any given health care system that long. So very rarely will I have all the measurements made on you.”

However, he adds, this isn’t the case in other countries, and cites the example of the Clalit in Israel, which he notes “published all the big COVID studies looking at the efficacy of the vaccine. And why could they do that? Because they had the whole population available, and they have about 20, 25 years’ worth of data on all of their patients in detail and family relationships.”

In the U.S., he asks, “Where is that data going to come from?” 

Some organizations in the U.S. believe “they can get enough data” on their own, he says, and cites the Mayo Clinic as one example. He also notes that “there are some data companies that are trying to get relationships with health care systems where they can get de-identified data,” although he doesn’t sound very optimistic about this approach.

Attia, for his part, strongly agrees that health data is exceedingly “unfriendly,” and cites a pain point from his own practice.

When lab tests are obtained for patients, he says, and “we want to generate our own internal reports based on those…it’s almost impossible to scrape those data out of the labs because they’re sending you PDF reports. Their APIs are garbage. Nothing about this is user friendly.”

“Just because our patients own the data doesn’t make it easy to get,” he continues. “There is no aspect of my practice that is more miserable and more inefficient than data acquisition from hospitals. It’s actually comical, absolutely comical.”

Attia adds, “Is there a more user-hostile industry from a data perspective than the health industry right now?”

Kohane agrees, and explains, “There’s a good reason why. Because they’re keeping you captive.”

Going forward, he says, he’s most concerned about the tendency of “the medical establishment” to “pour concrete over practices.” 

He explains that hospitals are huge entities that bring in huge revenue but have very small margins. In this situation, he argues, “you’re going to be very risk averse and you’re not going to want to change.” 

Consequently, while Kohane said he remains excited about the potential of new businesses that come up with ways of delivering data-driven insights to patients about their individual health needs, he’s concerned about what these startups are up against. Specifically, he warns of “hospitals doing a bunch of information blocking … that will make it harder for these new businesses to get created.”

Can Patients Drive Disruption?

A key theme of both Kohane’s recent book about GPT-4 (including in particular the sections written by co-author Carey Goldberg) as well as Kohane’s conversation with Attia is the embrace of generative AI tools by patients.  “They’re being used by patients all the time in ways that we had not anticipated,” Kohane says.

Kohane cites the example of a mom whose child had confusing symptoms that doctors struggled to synthesize into a diagnosis.  Frustrated, she typed the information into ChatGPT, which suggested something called “tethered cord syndrome,” subsequently confirmed by imaging.

At this point, Attia asks a critical question: was it surprising that none of the doctors had tried to use ChatGPT to assist with the diagnosis?

Kohane’s deeply discouraging response was that “most clinicians I know do not have what I used to call the Google Reflex” – the instinct to look up and pursue curious and confusing observations.

The reason, he suggests, is that “doctors are in a very unhappy position these days. They’re really being driven very, very hard,” and morphing “into data entry clerks.” 

Essentially, Kohane explains, physicians are too busy with the operational aspects of medicine – in particular, documentation and billing.  This means they have less time to think, and perhaps less incentive to think. 

(I anticipated and discussed this challenge – preserving creativity in medicine – 20 years ago, see here.)

Consequently, Kohane sees patients, and those invested the most in them (especially their families), as the most powerful disruptive force in medicine. 

(I’ve also emphasized the critical role of patients and families as key drivers of care – including in the NYT here, here, as well as in The Atlantic here).

Kohane points to patients without primary care doctors who might be worried about a rash, for example. They recognize that they have a power tool, he says, and given the choice between waiting months to potentially be seen or using the tool, they’ll use the tool.

“It’s better than no doctor for sure. And maybe better.”

Kohane also emphasizes that because patients have the legal right to their own data, even though accessing these data can often be difficult, the legal right creates opportunities. 

He points to Apple Health, which he says has partnered with 800 hospitals and makes it easy to get some of your key health data on your phone or computer. 

“Now, there’s not a lot of companies that are taking advantage of that,” he says, “but right now, that data is available on tens of millions of Americans.”

Kohane predicts that in “the next 10 years, there’ll be a company, at least one company that figures out how to use that patient’s right to access through dirty APIs, using AI to clean it up, provide decision support with human doctors or health professionals to create alternative businesses.”

Yet, he acknowledges, “I don’t want to underestimate the medical establishment’s ability to squish threats, so we’ll see.”

Bottom Line

Rapidly improving AI is likely to impact medicine by augmenting the capabilities of specialists, particularly those focused on visual diagnoses.  AI might also provide the expert insight to enable non-MDs to provide care in situations where MDs are increasingly unavailable.  The development of AI for clinically focused applications (in healthcare as well as in drug development) depends critically on the availability of relevant clinical data, which (despite the existence of at least some legislation) remains excruciatingly, maddingly, disturbingly difficult to pry from the grip of incumbent health organizations. 

But if these organizations are an immovable object, then patients and their families might represent an irresistible force, determined to leverage all available tools to accelerate diagnoses and identify potential treatments (David Fajgenbaum’s own miraculous story, as well as the journeys chronicled by Amy Dockser Markus, come to mind – see here).  Ideally, despite institutional and occupational hurdles, inquisitive physicians such as those celebrated by Judah Folkman will also drive the use and acceleration of AI technologies in service of improved patient care.

David Shaywitz

“It was all mixed into one, enormous, overflowing stew of very real technological advances, unfounded hype, wild predictions, and concerns for the future.  ‘Artificial intelligence’ was the term that described it all.” – Cade Metz, Genius Makers

The buzzy excitement around artificial intelligence (AI), and most recently generative artificial intelligence (genAI), has inspired some biopharma leaders, exasperated many others, and touched almost everyone.

Leading management consulting firms have sold an enormous amount of business by persuading biopharma companies that:

• They are already lagging dangerously behind their competitors on AI adoption;
• There are tremendous productivity gains to be found, and value to be created, in the expeditious adoption of AI.

Within biopharma R&D departments, most researchers remain predictably skeptical of the incessant hype, even as many are authentically curious about promising advances (like AlphaFold, whose inventors received the 2023 Lasker Award for Basic Medical Research).  They are also politically astute enough to genuflect to senior management’s imperative to demonstrate the organization’s embrace of AI. 

One result has been an AI version of innovation theater, where there’s all sorts of demonstration projects, working groups, PowerPoint decks, partnerships, and celebratory speechifying.  A huge amount of heat is generated, but so far, relatively little light.

At one level, none of this is surprising.  As I discussed in 2019 in the context of precision medicine, and more expansively in 2023 in the context of AI, it historically takes a very long time for us to figure out how to productively use new technologies.  As economic historians like Paul David, Carlota Perez, James Bessen, Robert Gordon, and others have consistently reminded us (as I discussed here), we don’t tend to wring productivity of out new technologies overnight; more typically, it takes decades, and many rounds of successive incremental innovations.

Yet, it’s easy to imagine, in the context of breathless pitches and extravagant promises, that perhaps this time it’s different – perhaps AI has found a way to beat the historical odds, and is leading to the sort of immediate, measurable productivity gains that enthusiasts promise and biopharma executives desperately seek.

For biopharma in particular, the excitement is understandable.  As visionaries like Mustafa Suleyman argues in The Coming Wave (my 2023 WSJ review here) and Jamie Metzl argues in Superconvergence (my just-published WSJ review here), the thesis that accelerating revolutions in biotech and AI are compounding each other, and leading us towards a promising, tech+bio future is not just compelling but directionally correct.  The question, of course, is when will we realize this AI-infused bio-rapture?

According to a recent, arresting Goldman Sachs (GS) report, entitled “GenAI: Too Much Spend, Too Little Benefit?” perhaps we shouldn’t hold our breath.

The GS report is worth reading in its entirety, but I’ll focus on several salient sections: an interview with the distinguished scholar and MIT economist Daron Acemoglu; an interview with GS’s Global Head of Equity Research Jim Covello, and an interview with two GS Senior Equity Research Analysts, Kash Rangan and Eric Sheridan.

Before we get to these details, it’s worth noting how refreshing it is to read a corporate document that conveys multiple, at times conflicting viewpoints around complex issues like the future state and anticipated economic impact of AI.  While top management consulting firms typically offer a singular, consensus view on topics like the path forward for AI, this report from GS acknowledges and systematically explores differences in perspectives and assumptions. The result is an unusually substantive and credible report that conveys nuance and embraces uncertainty.

Daron Acemoglu: Hopeful Skeptic

Daron Acemoglu is a distinguished economist at MIT and the co-author, most recently of Power and Progress.  A WSJ review by Deirdre McCloskey described Acemoglu as “a shoo-in for Nobel Prize” in economics, and said the book expressed the authors’ view that “The invisible hand of human creativity and innovation…requires the wise guidance of the state.”

Daron Acemoglu, Institute Professor, MIT

In his conversation with GS, Acemoglu expressed excitement about the promise of genAI, noting it “has the potential to fundamentally change the process of scientific discovery, research and development, innovation, new product and material testing, etc. as well as create new products and platforms.”

However, he cautioned, “these truly transformative changes won’t happen quickly and few—if any—will likely occur within the next 10 years.”

Instead, he suggests, “AI technology will instead primarily increase the efficiency of existing production processes by automating certain tasks or by making workers who perform these tasks more productive.”

He also thinks AI, even with more data and fancier chips, will still struggle with open-ended tasks, like improving “a customer service representative’s ability to help a customer troubleshoot problems with their video service.” 

In addition, like many others, Acemoglu worries “where more high-quality data [to power future AI models] will come from and whether it will be easily and cheaply available to AI models.”

He recognizes the future possibilities of genAI, he says, and hopes AI creates new tasks, products, business occupations, competences – but adds this is “not guaranteed.” 

While emphasizing that “Every human invention should be celebrated, and generative AI is a true human invention,” he is concerned that “too much optimism and hype may lead to the premature use of technologies that are not yet ready for prime time.”

Jim Covello: Pessimistic Skeptic

As Jim Covello, the Head of Global Equity Research at GS sees it, one critical concern around AI relates to the “substantial cost to develop and run” the technology; the investment only makes sense if AI can “solve extremely complex and important problems for enterprises.”  But solving complex problems, he says, is something the technology “isn’t designed to do.”

Covello challenges several familiar assertions used to justify current costs. 

“Many people attempt to compare AI today to the early days of the internet,” he says.  “But even in its infancy, the internet was a low-cost technology solution that enabled e-commerce to replace costly incumbent solutions.” 

In contrast, he argues, AI technology is starting out “exceptionally expensive.”

He adds that the idea that technology “typically starts out expensive before becoming cheaper is revisionist history.”  E-commerce, he asserts, “was cheaper from day 1.”

He also says we can’t count on AI prices declining significantly; the dramatic historical decrease in the price of semiconductor chips, he says, was due to fierce competition; but at least today, “Nvidia is the only company cable of producing the [computer chips] that power AI.”  Consequently, Nvidia is likely to maintain pricing power in the near-term.

Covello is also skeptical about the transformative potential of AI, arguing “people generally substantially overestimate what the technology is capable of today.”  He adds, “I struggle to believe that the technology will ever achieve the cognitive reasoning required to substantially augment or replace human interactions.”

He also contends, “Humans add the most value to complex tasks by identifying and understanding outliers and nuance in a way that it is difficult to imagine a model trained on historical data would ever be able to do.”

Covello points out that he was a semiconductor analyst when smartphones arrived and followed the evolution of smartphone functionality closely.  As he remembers it, the ensuing roadmap was clear, “with much of it playing out just as the industry had expected.”

In contrast, he argues, “No comparable roadmap exists today. AI bulls seem to just trust that use cases will proliferate as the technology evolves. But 18 months after the introduction of generative AI to the world, not one truly transformative—let alone cost-effective—application has been found.”

Of particular relevance for biopharma, he notes that “companies outside of the tech sector … face intense investor pressure to pursue AI strategies even though these strategies have yet to yield results. Some investors have accepted that it may take time for these strategies to pay off, but others aren’t buying that argument.”

He warns that “The more time that passes without significant AI applications, the more challenging the AI story will become. And my guess is that if important use cases don’t start to become more apparent in the next 12-18 months, investor enthusiasm may begin to fade.”

Rangan and Sheridan: Long-term Optimists

A somewhat more positive perspective on genAI, at least in the long-term, was expressed by Kash Rangan and Eric Sheridan, both Senior Equity Research Analysts at GS.

Noting that “hardly a week goes by without reports of a new, and better, AI model,” Rangan said he remained enthusiastic about genAI long-term potential, but acknowledged, “we have yet to identify AI’s ’killer application.’ ”  

Similarly, while acknowledging that the technology “is still very much a work in progress,” Sheridan said “it’s impossible to sit through demonstrations of generative AI’s capabilities at company events or developer conferences and not come away excited by the long-term potential.”

Rangan acknowledges that “AI technology is undoubtedly expensive today” but argues (in contrast to Covello) that “the cost-equation will change.” 

Pointing out that “people tend to overestimate a technology’s short-term effects and underestimate its long-term effect,” Rangan adds “Nobody today can say what killer applications will emerge from AI technology. But we should be open to the very real possibility that AI’s cost equation will change, leading to the development of applications that we can’t yet imagine.”

Sheridan agrees the economics of AI are challenging now: “I readily acknowledge that the return on invested capital (ROIC) visibility is currently low, and the transformative potential of AI will remain hotly debated until that becomes clearer.” 

He concludes, “people didn’t think they needed smartphones, Uber, or Airbnb before they existed. But today it seems unthinkable that people ever resisted such technological progress. And that will almost certainly prove true for generative AI technology as well.”

Concluding thoughts

I remain optimistic and energized by the promise to be found at the intersection of AI and biotechnology, and view digital technologies like AI as increasingly essential tools for understanding biology as well as for effectively managing biopharma R&D.  But even if at times genAI seems magical, we can’t treat it as magic.  We can’t operationalize it as magic.  We can’t invoke it as a force that will descend from the rafters, deus ex machina, and somehow fix what ails our organizations.  Nor should we set it aside, dismissing it simply the newest new thing.  By steering a path between credulous mysticism on the one hand, and reflexive cynicism on the other, we can inquisitively explore and thoughtfully interrogate this powerful emerging technology, and identify meaningful opportunities for productive application in biopharma R&D.

David Shaywitz

While visiting my parents on Memorial Day weekend, I reflected on the wonder and joy of a life in medicine and science — theirs as well as mine. 

Incredible Progress in Medicine

My parents are academic physician-scientists at Yale Medical School, where they founded and continue to lead the Yale Center for Dyslexia and Creativity. Now in their early 80s, they are as active and engaged as ever, reading the literature, leading a research team, and giving talks. Just a year or so ago, their Coursera course, “Overcoming Dyslexia” went live, and has now enrolled over 40,000 learners.

David, Sally and Bennett Shaywitz

On the morning of Memorial Day, my dad and I, both early risers, were sipping coffees at the kitchen table when he began to reflect on how much medicine has changed over the course of his career in pediatric neurology.

He described clinical neurology before contemporary neuroimaging like CT and MRI scans.  Before their arrival, my dad said, neurologists had few tools beyond the classic neurological exam, an approach that is elegant, even charming in theory, but historically has been largely unfalsifiable in practice.  This changed, he said, when noninvasive neuroimaging arrived and gradually revealed the limitations and often specious conclusions of the beloved physical exam. 

Procedures were different as well. In the days before advanced noninvasive imaging, I was told, children with meningitis often received a subdural tap, meaning a needle was stuck into the skull to remove a potential effusion (fluid buildup). With the advent of CT imaging, neurologists quickly learned that effusions were common in these patients and would typically resolve on their own.  Bacterial meningitis itself has become far less common than it was decades ago, due to the introduction of vaccines that protect against the most common causes. 

My mom, who soon joined us at the table, reminded me that imaging also impacted other medical specialties, including obstetrics. When she was pregnant with twins, I learned, doctors struggled to make this determination; a plain X-ray film (with its associated radiation exposure) was ultimately required to be certain. Obstetrics was considerably riskier than today, and pediatricians (particularly pediatric neurologists) would often see infants with injuries from difficult deliveries.

It was also common, my mom recalled, for pediatricians to encounter children who suffered from viral conditions now preventable with vaccines. She saw many kids who were born deaf following maternal infection with rubella. There were also a number of children each year who she saw die from measles. In addition, it was not unusual to encounter adults (including my mom’s best friend) who were crippled because of a polio infection in childhood.

My parents also recall frequently seeing young patients with lead poisoning. Sometimes children would come in with seizures, or occasionally in a coma, because of lead-induced encephalopathy. Often, this happened when small children would pick up and eat bits of lead-containing paint. Since the late 1970s, when the manufacture of lead-based paint was banned and awareness of the health risks rose, fewer kids now suffer these symptoms.

(I would be remiss not to point out that our ability to identify and effectively support children and adults with dyslexia is also far better than it was years ago, reflecting the work of researchers like my parents and others.)

The progress my parents have seen across their careers – largely attributable to improved imaging technology, the development of highly effective vaccines, and impactful public health measures likes universal childhood vaccinations and the mandated removal of lead — is extraordinary. The capabilities we have today to diagnose and treat illness are so much more powerful than when they started.  To me, this reinforces why, if asked the question “If you could pick any time to live, when would you choose?” the response must be today — unless tomorrow is an option. 

Things are getting better – as neuroscientist Steven Pinker, among others, reminds us.

To be sure, while improved technology and medicines offer the possibility of better health, this promise will only be realized through access, and this remains a profound concern. A recent Wall Street Journal headline announced, “Cancer is Capsizing Americans’ Finances,” while a recent South Park lampooned the byzantine process required in the U.S. healthcare system to access GLP-1 medicines for diabetes and weight loss. 

Our challenge here is finding a way to address the urgent need to ensure access to the best care available today while simultaneously continuing to incentivize the development of even better diagnostics and therapeutics (including those like vaccines aimed at preventing rather than treating disease) for future generations.

Craig Garthwaite, professor of strategy, Northwestern University’s Kellogg School of Management

As Craig Garthwaite, a health economist at Northwestern University, nicely frames it, the need for better treatments can be seen as another category of access challenge. 

“I’ve lost close family members to cancer that didn’t yet have treatments available,” he writes. “The hardest part for them wasn’t affording it. A lack of innovation is the access problem we often overlook because it isn’t as salient — but it is a far larger barrier than price (emphasis added).”

Today, no one can access desperately needed transformative medicines for conditions like glioblastoma, pancreatic cancer, and Alzheimer’s Disease; they haven’t been invented yet.

Diversity of Global Science

While home, I also came across mementos I saved from lab experiences over the years. One example: a 24-well plate signed and gifted to me nearly four decades ago by a colleague (now a professor at UCSF) in tribute to the weeks we spent one summer in the Janeway lab at Yale doing an assay using these plates over and over (and over).

Reflecting on my experiences in science, both in academia and industry, I was struck by the incredible diversity of people I’ve worked with, reflecting so many different paths and life experiences and even politics. 

For instance, while most researchers tend to shade to the left, I vividly remember a phenomenal technician from the Janeway lab who proudly wore a belt buckle proclaiming “God, Guns, and Guts Made America Great.” I also recall a postdoc from my PhD lab who was emphatically pro-life, and who has gone on to a highly successful career in science, now leading drug discovery at a prominent AI company.

Science is intrinsically international. Difficult and compelling problems attract passionate researchers from across the world. An incredible privilege of a life in and around science is how second nature it becomes to collaborate with colleagues from everywhere. 

In college, I learned molecular biology next to brilliant colleagues who had grown up in places like India and Iran and are now accomplished biomedical scientists and entrepreneurs. In the labs I’ve worked in, it was routine to see a postdoc from South America next to a postdoc from Eastern Europe next to a graduate student from Michigan. 

Scientists at the companies where I’ve worked also came from around the globe; in my last role, at a company headquartered in Japan, the Chief Data and Technology Officer hailed (very, very proudly) from Ireland; innovation in pharmaceutical sciences was driven by a brilliant colleague from Austria; and the physician-scientist leading the gastroenterology, immunology, and inflammation therapeutic area had emigrated from Nigeria when he was eighteen.

Diversity in science includes religion as well. 

In the Tonegawa lab, at MIT, a Mormon graduate student helped me better understand the purpose and fulfillment of missions. At Takeda, a talented epidemiologist and officemate shared his experience fasting for Ramadan, and the joy of Eid al-Fitr as the month-long observance concludes.

That’s not to say, of course, that science is as representative as it needs to be if it is to truly capture the full potential of the most capable minds in the world. In my last role, an exceptionally effective African-American vice president and science technology leader would poignantly lament how few African-American colleagues there were at senior levels in the organization, a disparity he worked passionately to address.

Compared to the perfect state, science clearly has a distance to go. 

But there is so much about the community of science that is encouraging, including its ability to attract global talent with diverse viewpoints to pursue collaboratively the shared goal of better understanding nature, and if we’re lucky, translating this understanding into more effective treatments for patients wherever they live, and whatever their politics and beliefs.

Good Listens

My drive from Massachusetts to Connecticut also afforded me the opportunity to catch up on some podcasts; here are a few episodes that might be of interest.

• Acquired episode, discussing Microsoft’s early days. Fun fact: Windows was Plan B. 
• WSJ – The Future of Everything episode featuring the always interesting “Science of Success” columnist Ben Cohen discussing how Birkenstock’s became such a big deal.
• Invest Like The Best episode, discussing how Mitch Rales built Danaher into the life science tools colossus it is today.
• Running Through Walls episode – Venrock’s Bob Kocher sits down with Mark McKenna, the former CEO of Prometheus, which was acquired last year by Merck for $10.8B.
• Honestly podcast: for readers looking for a fresh perspective on journalism-related topics, two recent episodes may be of interest:
  • Here, host (and former New York Times reporter) Bari Weiss interviews (former) NPR senior reporter Uri Berliner about how the media business is changing;
  • Here, Weiss interviews (former) New York Times reporter Nellie Bowles about Bowles’s recently published Morning After the Revolution – one of my favorite recent reads.

David Shaywitz

The two broad categories of medical discovery that command the most attention are insights resulting from rare, informative genetic conditions (see here) and advances resulting from fortuitous observations.  

A canonical example of the value of extreme genetic phenotypes is the patient with familial hypercholesterolemia who inspired Brown and Goldstein’s scientific pursuit of cholesterol metabolism and led to the statins. Similarly, Vertex’s promising pain medicine was directly inspired by rare genetic conditions associated with pain hypersensitivity and hyposensitivity.   

Meanwhile, as we’ve discussed frequently in this column, many medicines, particularly in neuroscience, have been discovered by “happy accidents” – tricyclic antidepressants are one example.

Decades of Painstaking Science

But GLP-1 medicines like semaglutide (Wegovy) and tirzepatide (Zepbound) do not fall into either of these categories. Their development reflects decades of meticulous biology and physiology, of researchers working slowly and painstakingly through the complicated science.

Daniel Drucker, professor of medicine, Lunenfeld Tanenbaum Research Institute of Mt. Sinai Hospital and the University of Toronto.

As pioneering researcher Daniel Drucker and colleagues wrote in a comprehensive review in 2017, “the field was built slowly with a series of non flashy yet solid studies examining the physiology, pharmacology, and pleiotropic actions of native GLP-1 and multiple GLP-1R agonists.”

Drucker notes that most papers in the GLP-1 field (at least until recently, one imagines) “were published in traditional physiology or endocrinology subspecialty journals and might be described as ‘descriptive’ or ‘incremental’ by many colleagues.”

His summary:

“Taken together, the story of discovery and characterization of the GLP’s highlights how old-fashioned biochemistry, physiology, molecular biology, and traditional analyses of hormone action provides a firm scientific foundation for the development of multiple novel therapeutics for the treatment of obesity, diabetes, and intestinal disorders.”

To put a finer point on it: genetics were not a key component of the GLP-1 story.  Drucker explicitly pointed this out in his interview with Eric Topol (discussed in previous column), noting that physiologically, removal of GLP-1 or GLP-1 receptor doesn’t seem to have profound consequences. In contrast, molecules identified through genetic analysis, like leptin, have not proven to be of great therapeutic utility.

Similarly, the potential of GLP-1 medicines to cause weight loss was also not a happy accident – rather, it was seen from some of the earliest rodent studies of GLP-1, and a key thesis of the Novo GLP-1 program from the earliest days. 

Key Enablers and Challenges

There were some lucky breaks, to be sure. 

For one, as discussed in my last column, the adverse effects associated with GLP-1 initiation – nausea and vomiting in particular – generally wane over time, while the therapeutic effect (suppression of appetite) endures. 

The biology could easily have gone the opposite way. 

Also helpful: encouraging results from large cardiovascular outcome studies for long-acting GLP-1 medicines used for the treatment of diabetes (high-risk patients were found to have a significantly lower rate of adverse cardiovascular events – here, here). 

These results, together with a decade of reassuring experience using GLP-1. The first, exenatide (Byetta), was approved by the FDA for use in diabetes in 2005. That molecule, originally a twice-daily injection and then formulated into a LAR version allowing once-weekly injection, helped provide confidence in the safety of this class.

Weight loss was consistently observed in patients with type 2 diabetes. The clean safety profile over time, combined with the long-term cardiovascular benefit, helped encourage companies to take a shot at a much larger patient population – people who are overweight or obese but don’t have diabetes.

Drucker acknowledges that translation of promising GLP-1 science into approved therapeutics was a particularly challenging task that required decades. 

He cites several hurdles, including:

• Need for a longer-acting peptide (endogenous GLP-1 has an incredibly short half-life in the blood – only about two minutes); legendary Novo researcher Lotte Bjerre Knudsen famously spent years focused on figuring out how to create a longer-lasting therapeutic version this before finally developing a solution that become liraglutide (Victoza), a once-daily injection.
• Need to figure out dosing to address GI side effects; Drucker points out that in every clinical study, GLP-1 medicines cause GI discomfort including nausea and vomiting; eventually, Drucker says, researchers recognized that these side effects can be significantly mitigated through slow titration.
• Need for better assay reagents to detect levels of key molecules like GLP-1, GLP-2, and their receptors. Some large pharmas have analytic lab groups specifically focused on developing such tests for R&D; I recall a particularly capable team at Merck Research Labs in Rahway, NJ when I was there nearly 20 years ago.

New diabetes medicines – as well as potential obesity medicines – also require large cardiovascular outcome trials, to prove that the benefit delivered by these medicines outweigh any risk.

These concerns were motivated on the diabetes side by the experience of GSK’s rosiglitazone (Avandia), an insulin sensitizer which seemed to have a positive effect on diabetes parameters but, unexpectedly, a negative effect on cardiovascular outcomes. The high-profile safety controversy led the FDA to mandate cardiovascular outcome trials for future diabetes medicines – a move that added considerable time and cost to type 2 diabetes R&D programs. 

Obesity medicines have long concerned regulators both because of the perception that they might be widely utilized as so-called lifestyle medicines, and more specifically because of the experience with the combined use of two drugs individually approved by the FDA, fenfluramine and phentermine. Used together (“fen-phen”), the combo caused some patients to develop valvular heart disease and pulmonary hypertension.

The key point here is that in many ways, GLP-1 drugs were ideally suited for large pharmas, given the time, resources, and range of expertise required to address all of these drug development challenges. 

Lessons for Drug Developers

I asked Drucker what he saw as the key lessons for drug development. He cited three.

• “We should embrace multiple lines of evidence, and not just pursue human genetics-based leads”
• “Nice to use human genetics to screen out for worrisome oppositional signals or for supportive directional biology but not exclusively as a must-have criteria (or we would not have SGLT2i in heart and kidney disease, or GLP-1RAs etc)”
• “The solid reproducible non-flashy tortoise (careful papers in solid mid-tier journals) often beats the spectacular Nature/Science/Cell”

There may be an addition lesson as well.

In reviewing Drucker’s many publications, I was struck by the insight and brilliance that seemed to be required to drive the science in this complicated area. Yet when I put this to Drucker, he suggested instead that the most important attributes he’s brought to the field were his tendency to be “careful, persistent, and tenacious.” 

I suspect these characteristics apply to the vast majority of successful drug developers.

We’re often attracted to the idea of science and drug development advancing through a series of brilliant ideas, eureka moments, and incandescent insights. Without question, narratives with these features make compelling stories.

Yet in the case of the GLP-1s, a category of medicine that is poised to transform everything in our world, these blockbuster medicines seem to have resulted from something quite different: decades of slow, determined science, both on the part of academics like Drucker, and companies like Novo and Lilly, patiently and deliberately nudging the work relentlessly forward.

Prediction is Hard

Finally, just to emphasize how difficult the future is to predict in medicine and science, even by the most informed experts, I feel obliged to call out a particularly revealing sentence from Drucker’s 2017 review.

Drucker writes, “market penetration for many GLP-1R agonists remains disappointing, raising questions about the potential clinical appeal, expense, and commercial success of newer formulations.” 

In other words, as recently as 2017 — twelve years after the first FDA-approved GLP-1 medicine, exenatide (Byetta) for diabetes, and three years after the approval of liraglutide for obesity (marketed as Saxenda), after previous approval for diabetes (as Victoza) — it was clearly not a foregone conclusion that GLP-1 molecules were tracking to be the blockbuster obesity drugs they are today.

Michael Moritz

As legendary Sequoia VC Michael Moritz said (and as I recently discussed here), even great successes aren’t obvious early on: “I have never been involved in an investment that became a very successful business without fearing earlier that the business was going to fail, not even once.”

The problem, as Judah Folkman observed, is that to succeed, you have to proceed with conviction, but you don’t know until the end (in the case of the GLP-1 drugs, the randomized controlled trials demonstrating profound weight loss) whether you’re persistent or obstinate.

So where does this leave R&D leaders? 

One thought: we should be humbled by the challenges of forecasting, cognizant of the limitations of genetics (useful as it often can be) or of any single approach to drug discovery, inspired by accomplishments of determined academic researchers and pharmaceutical scientists, awed by the intriguing complexity of human biology, and deeply grateful for our collective opportunity, as contemporary drug developers with an unprecedented set of tools and capabilities, to fashion transformative new medicines for patients.