Regulatory considerations for digital therapeutics

While the development of digital therapeutics for urological conditions is in its infancy, other specialties have seen FDA approvals following submission of trial data demonstrating superiority, using both de novo and 510(k) pathways for medical devices. Others, namely Cognoa, who partnered with EVERSANA, received Breakthrough Designation from the FDA for their digital diagnostic and therapeutic for autism spectrum disorder. To put this in context, Breakthrough Designation is awarded by the FDA to help expedite the development and approval of treatments that treat a serious condition and where preliminary clinical evidence indicates that the treatment may demonstrate substantial improvement over available therapies on a clinically significant endpoint. The FDA clarifies that clinically significant endpoints are those that measure an effect on irreversible morbidity (or mortality), further punctuating the recognition that digital therapeutics can disrupt and offer real benefits over pharmaceutical or other treatments, which have been the mainstay of therapy for a number of conditions for over half a century.

The regulatory framework for the approval of digital therapeutic interventions is not as defined as that for physical devices or pharmaceuticals. In 2017, the FDA introduced a Software Precertification Pilot Program which aimed to help inform the development of a regulatory model to assess such innovations. While the FDA has subsequently released discussion documents and draft guidance is available, it is clear that a comprehensive and well-defined pathway requires a great deal of time and many case examples before more certainty exists for those developing such therapies.

In the United States of America, some digital therapeutics must undergo randomized controlled trials under the premarket approval process to demonstrate acceptable safety and efficacy. Digital therapeutics are inherently different though from pharmaceuticals, the form of which remains stable and composition unchanged over time. Many digital therapeutics that are essentially software as a medical device have the potential and indeed often require frequent updates following FDA review, much as the operating system on servers, computers, and smart devices do. Other digital therapeutics that utilize machine learning or other artificial intelligence (AI) as a component may evolve as they “learn” the optimal features over time.

Digital therapeutics in urology

The current field of digital therapeutics is largely focused on chronic conditions or those that are modifiable by means of behavioral change. The therapy, which was otherwise an in-person service, is provided as a digital product which may be over-the-counter or prescription only. Similar to a prescription medicine, the prescription-only digital therapeutic is prescribed and the patient is ultimately directed to the manufacturer who, by various means, enrolls the patient onto the digital therapeutic. Digital therapies often make use of an access code or other time-constrained access modality to enable the use of a mobile application as prescribed and as per the digital therapeutics approved label. Web dashboards are often available, which allow patients and physicians to monitor progress and compliance. While the field of digital therapeutics is still in its infancy, the number of approved and available therapies currently focused on patients exclusively with urological conditions is limited. Throughout this chapter, an overview is provided of digital therapeutics currently approved or in development in contexts which are relevant to urology. While some may currently be approved for specific conditions, they are of utility to the care of patients with urological complaints, which may benefit the urologist in helping to provide more holistic care and may even provide inspiration for adaption and help improve care of patients with other conditions.

Preventative care

Livongo is a digital therapeutic product for diabetes, diabetes prevention, weight management, and hypertension. It is, however, not FDA approved. It is still commercially available though. Livongo is operated by Teladoc Health, a large virtual care company, which says they are “creating a truly unified and personalized consumer experience; developing technologies to connect to patients and extend the reach of care providers; delivering the highest standard of clinical quality at every touchpoint; and enhancing health decisions and outcomes with smart data and actionable insights.” They are by their own description a consumer company, and despite their name, are not a health company. The underlying concept though, allows for preventative care which is relevant to those with metabolic syndrome, for example, a condition highly prevalent amongst urology patients—and was present in ∼39% in a study conducted in male urology patients ( ).

Wellthy CARE Digital Therapeutics Platform also provides an offering for lifestyle modification and enables weight loss in patients with obesity and metabolic syndrome. They offer a yearlong program, which includes a health coach, supports for diet modification, physical activity, and remote patient monitoring of glycemic control and blood pressure. They conducted a single arm study involving 196 participants over a period of 52 weeks ( ). While there was no control arm, those who were in the highest quartile in terms of app engagement lost 3 kg of weight compared to those in the lowest quartile who lost 1.2 kg. While further work is required to fully validate this specific platform, it does offer a positive signal of the potential utility of such interventions in preventative care.

Preoperative assessment

Urologic patients undergoing surgical procedures require careful preoperative evaluation and planning prior to surgery. Failure to assess the preoperative needs of these patients could potentially lead to increased intraoperative and/or postoperative morbidity. The effect may be temporary, such as increased postoperative dementia in geriatric patients taking certain preoperative medications ( ), or more insidious, as seen with increased complications in patients with suboptimal nutrition prior to radical cystectomy ( ). In addition to increased morbidity, an incomplete preoperative assessment can have financial implications for both the patient and the hospital system. For example, a prospective cross-sectional study from 2011 looked at surgical cancellation rates in 25 hospitals and found that approximately 8% of elective urological surgeries were canceled and rescheduled within 24 h of the scheduled procedure ( ). Medical administrative reasons, such as incomplete medical work, have been cited as a major source of many of the cancellations. Such digital tools and therapies can help improve patient compliance with pre-operative care instructions, and with nutritional status, and even help in the completion of the pre-operative assessment itself.

Managing chronic conditions

Another robot doing in the rounds is Catalia Health’s Mabu. Mabu, an abbreviated form of the Japanese word “Mabudachi”, meaning close friend, uses AI and psychological modeling to encourage and motivate people to take their medications. It isn’t just an alarm clock on wheels, but it aims to build relationships with patients and customizes its conversations to keep patients adhering to dosing regimens for longer. It is currently being used in helping patients with congestive heart failure, rheumatoid arthritis, chronic kidney disease as well as being integrated into clinical trials to help record and report patient reported outcomes and improve treatment adherence in ambulatory trials. It can also be used to facilitate telemedicine visits and also connects with other devices to collect and report data. The solution offered by Catalia Health does not require the user to configure the robot in anyway, other than turn it on when they unbox the robot. As it is equipped with its own cellular modem, it aims to be more accessible to more patients, independently report data and provide 24/7 monitoring or as programmed.

Proteus Digital Health spent almost 20 years developing ingestible sensors and gained regulatory approval in 2017 for its “smart pill” from the FDA. The technology is incorporated into medications; a feat possible because the sensor employed was the size of a grain of sand and is coated on one side with copper and on the other with magnesium. When the pill is swallowed, gastric acid helps complete the circuit and generates a detectable, albeit tiny, electric current, which is detected by a sensor patch worn by the patient on their abdomen. This in turn connects with a mobile app and can be shared with those monitoring compliance. It helps complete a timestamp of when the medication was actually taken and so can determine adherence and compliance with a level of accuracy and granularity, which is hard to match for an oral ingestible medication which is self-administered. The patch is also a multimodal sensor and can measure activity and sleeping patterns, heart rate, and temperature. Some of the potential applications of the system included improving access to medications. Some payers and health systems will not provide some high-cost treatments to patients who are at risk of nonadherence. A pilot study examining this claim was performed and included 28 patients who were given treatment for hepatitis C that incorporated the smart pill technology. Of the 28 participants, 26 were cured and 94% of prescribed doses were taken ( ). While this technology, its development, and the achievements of those who developed it and validated its utility are to be commended, it should also be noted that it may be used as a cautionary tale. At its pinnacle, Proteus Digital Health were valued at over $1.5 billion US dollars, and despite FDA approval of their technology in 2017, they were bankrupt by 2020, when their underlying assets including intellectual property were bought for $15 million US dollars by a pharmaceutical company who clearly understand the value proposition of the technology.

A multicenter randomized controlled trial of pelvic floor muscle training with a motion-based digital therapeutic device was performed versus pelvic floor muscle training alone for the treatment of stress-predominant urinary incontinence by a group of investigators from Massachusetts General Hospital, Northwestern University, the University of Oklahoma, Cedars Sinai, the Cleveland Clinic, Eastern Virginia Medical School, and the University of Alabama, and published in January 2022. They randomized 77 women but had to halt the trial early due to device technical considerations. However, before termination, those randomized to the intervention group installed a mobile application to their smartphone and paired with the device: Renovia Inc’s leva digital therapeutic, which is an intravaginal insert equipped with accelerometers and which communicates wirelessly with the smartphone app. This in turn provides visual feedback to the patient. After 8 weeks, the primary outcomes, including change in Urinary Distress Inventory and the Patient Global Impression of Improvement, did not show any improvement between groups; however, the median number of stress urinary incontinence (SUI) episodes decreased from baseline by 1.7 per day in the intervention group compared to 0.7 in the control group, P = .047 ( ).

A subsequent and larger prospective randomized controlled superiority trial, conducted remotely from September 2020 to March 2021, had 363 patients randomized to the same intervention as described in the earlier study by Weinstein et al. This larger subsequent study was powered to detect a difference in efficacy of pelvic floor training by using the levia digital therapeutic device with a home training program to reduce severity of symptoms and episodes of urinary incontinence. This trial demonstrated a significant reduction in both the median number of SUI episodes on the 3-day bladder diary (4 episode reduction vs. 3 episode reduction for the control group; P = .005) and also demonstrated significant improvements in both the UDI-6 score and PGI-I score ( ).