Global Wound Prevalence Forecast by Type, 2016-2026

The clinical driver of sales in wound care is the prevalence of different wound types and the associated cost to manage them. While surgical wounds made by primary intent as part of surgical procedures (e.g., excision of skin lesion, appendectomy, coronary artery bypass graft, etc.) represent the biggest source of wounds, the biggest focus on reining in costs in medtech is slow-healing, chronic wounds, such as ulcers.

We have projected the global prevalence for the most common wound types through 2026, shown below.

Source: MedMarket Diligence, LLC; Report #S254(Request excerpts.)

 

Six key trends in the market for surgical sealants

Here are six key trends we see in the global market for surgical sealants, glues, and hemostats:

1.  Aggressive development of products (including by universities, startups, established competitors), regulatory approvals, and new product introductions continues in the U.S., Europe, and Asia/Pacific (mostly Japan, Korea) to satisfy the growing volume of surgical procedures globally.

 Source: Report #S290. “Worldwide Markets for Medical and Surgical Sealants, Glues, and Hemostats, 2015-2022.”

2. Rapid adoption of sealants, glues, hemostats in China will drive much of the global market for these products, but other nations in the region are also big consumers, with more of the potential caseload already tapped than the rising economic China giant. Japan is a big developer and user of wound product consumer. Per capital demand is also higher in some countries like Japan.

3. Flattening markets in the U.S. and Europe (where home-based manufacturers are looking more at emerging markets), with Europe in particular focused intently on lowering healthcare costs.

4. The M&A and deal-making that has taken place over the past few years (Bristol-Myers Squibb, The Medicines Company, Cohera Medical, Medafor, CR Bard, Tenaxis, Mallinckrodt, Xcede Technologies, etc.) will continue as market penetration turns to consolidation.

5. Growing development on two fronts: (1) clinical specialty and/or application specific product formulation, and (2) all purpose products that provide faster sealing, hemostasis, or closure for general wound applications for internal and external use.

6. Bioglues already hold the lead in global medical glue sales, and more are being developed, but there are also numerous biologically-inspired, though not -derived, glues in the starting blocks that will displace bioglue shares. Nanotech also has its tiny fingers in this pie, as well.

See Report #S290, “Worldwide Sealants, Glues, and Hemostats Markets, 2015-2022”.

The future of medicine in 2037

In the post below from 2016, we wrote of what we can expect for medicine 20 years into the future. We review and revise it anew here.

An important determinant of “where medicine will be” in 2035 is the set of dynamics and forces behind healthcare delivery systems, including primarily the payment method, especially regarding reimbursement. It is clear that some form of reform in healthcare will result in a consolidation of the infrastructure paying for and managing patient populations. The infrastructure is bloated and expensive, unnecessarily adding to costs that neither the federal government nor individuals can sustain. This is not to say that I predict movement to a single payer system — that is just one perceived solution to the problem. There are far too many costs in healthcare that offer no benefits in terms of quality; indeed, such costs are a true impediment to quality. Funds that go to infrastructure (insurance companies and other intermediaries) and the demands they put on healthcare delivery work directly against quality of care. So, in the U.S., whether the Affordable Care Act (“Obamacare”) persists (most likely) or is replaced with a single payer system, state administered healthcare (exchanges) or some other as-yet-unidentified form, there will be change in how healthcare is delivered from a cost/management perspective.  -[Editor’s note: After multiple attempts by the GOP to “repeal and replace”, the strengths of Obamacare have outweighed its weaknesses in the minds of voters who have thus voiced their opinions to their representatives, many seeking reelection in 2018.]

From the clinical practice and technology side, there will be enormous changes to healthcare. Here are examples of what I see from tracking trends in clinical practice and medical technology development:

  • Cancer 5 year survival rates will, for many cancers, be well over 90%. Cancer will largely be transformed in most cases to chronic disease that can be effectively managed by surgery, immunology, chemotherapy and other interventions. Cancer and genomics, in particular, has been a lucrative study (see The Cancer Genome Atlas). Immunotherapy developments are also expected to be part of many oncology solutions. Cancer has been a tenacious foe, and remains one we will be fighting for a long time, but the fight will have changed from virtually incapacitating the patient to following protocols that keep cancer in check, if not cure/prevent it.
    [Editor’s note: Immunology has surged in a wide range of cancer-related research yielding new weapons to cure cancer or render it to routine clinical management.]
  • Diabetes Type 1 (juvenile onset) will be managed in most patients by an “artificial pancreas”, a closed loop glucometer and insulin pump that will self-regulate blood glucose levels. OR, stem cell or other cell therapies may well achieve success in restoring normal insulin production and glucose metabolism in Type 1 patients. The odds are better that a practical, affordable artificial pancreas will developed than stem or other cell therapy, but both technologies are moving aggressively and will gain dramatic successes within 20 years.

Developments in the field of the “artificial pancreas” have recently gathered considerable pace, such that, by 2035, type 1 blood glucose management may be no more onerous than a house thermostat due to the sophistication and ease-of-use made possible with the closed loop, biofeedback capabilities of the integrated glucometer, insulin pump and the algorithms that drive it, but that will not be the end of the development of better options for type 1 diabetics. Cell therapy for type 1 diabetes, which may be readily achieved by one or more of a wide variety of cellular approaches and product forms (including cell/device hybrids) may well have progressed by 2035 to become another viable alternative for type 1 diabetics. [Editor’s note: Our view of this stands, as artificial pancreases are maturing in development and reaching markets. Cell therapy still offers the most “cure-like” result, which is likely to happen within the next 20 years.]

  • Diabetes Type 2 (adult onset) will be a significant problem, governed as it is by different dynamics than Type 1. A large body of evidence will exist that shows dramatically reduced incidence of Type 2 associated with obesity management (gastric bypass, satiety drugs, etc.) that will mitigate the growing prevalence of Type 2, but research into pharmacologic or other therapies may at best achieve only modest advances. The problem will reside in the complexity of different Type 2 manifestation, the late onset of the condition in patients who are resistant to the necessary changes in lifestyle and the global epidemic that will challenge dissemination of new technologies and clinical practices to third world populations.

Despite increasing levels of attention being raised to the burden of type 2 worldwide, including all its sequellae (vascular, retinal, kidney and other diseases), the pace of growth globally in type 2 is still such that it will represent a problem and target for pharma, biotech, medical device, and other disciplines. [Editor’s note: the burden of Type 2 on people, families, communities, and governments globally should motivate policy, legislation, and other action, but global initiatives have a long way to travel.]

  • Cell therapy and tissue engineering will offer an enormous number of solutions for conditions currently treated inadequately, if at all. Below is an illustration of the range of applications currently available or in development, a list that will expand (along with successes in each) over the next 20 years.

    Cell therapy will have deeply penetrated virtually every medical specialty by 2035. Most advanced will be those that target less complex tissues: bone, muscle, skin, and select internal organ tissues (e.g., bioengineered bladder, others). However, development will have also followed the money. Currently, development and use of conventional technologies in areas like cardiology, vascular, and neurology entails high expenditure that creates enormous investment incentive that will drive steady development of cell therapy and tissue engineering over the next 20 years, with the goal of better, more long-term and/or less costly solutions.
  • Gene therapy will be an option for a majority of genetically-based diseases (especially inherited diseases) and will offer clinical options for non-inherited conditions. Advances in the analysis of inheritance and expression of genes will also enable advanced interventions to either ameliorate or actually preempt the onset of genetic disease.

    As the human genome is the engineering plans for the human body, it is a potential mother lode for the future of medicine, but it remains a complex set of plans to elucidate and exploit for the development of therapies. While genetically-based diseases may readily be addressed by gene therapies in 2035, the host of other diseases that do not have obvious genetic components will resist giving up easy gene therapy solutions. Then again, within 20 years a number of reasonable advances in understanding and intervention could open the gate to widespread “gene therapy” (in some sense) for a breadth of diseases and conditions. [Editor’s note: CRISPR and other gene-editing techniques have accelerated the pace at which practical and affordable gene-therapies will reach the market.]
  • Drug development will be dramatically more sophisticated, reducing the development time and cost while resulting in drugs that are far more clinically effective (and less prone to side effects). [Editor’s note: We are revising our optimism about drug development being more sophisticated and streamlined. To a measurable degree, “distributed processing systems” have proven far more exciting in principle than practice, since results — marketable drugs derived this way — have been scant. We remain optimistic as a result of the rapid emergence of artificial intelligence (AI) and deep learning, which have have very credible promise to impact swaths of industry, especially in medicine.]
    This arises from drug candidates being evaluated via distributed processing systems (or quantum computer systems) that can predict efficacy and side effect without need of expensive and exhaustive animal or human testing.The development of effective drugs will have been accelerated by both modeling systems and increases in our understanding of disease and trauma, including pharmacogenomics to predict drug response. It may not as readily follow that the costs will be reduced, something that may only happen as a result of policy decisions.

  • Most surgical procedures will achieve the ability to be virtually non-invasive. Natural orifice transluminal endoscopic surgery (NOTES) will enable highly sophisticated surgery without ever making an abdominal or other (external) incision. Technologies like “gamma knife” and similar will have the ability to destroy tumors or ablate pathological tissue via completely external, energy-based systems. [Editor’s note: In the late 1980s, laparoscopy revolutionized surgery for its less invasiveness. Now, NOTES procedures and external energy technologies (e.g., gamma knife) have now proven to be about as minimally invasive as medical devices can be. To be even less invasive will require development of drugs (including biotechs) that succeed as therapeutic alternatives to any kind of surgery.]

    By 2035, technologies such as these will measurably reduce inpatient stays, on a per capita basis, since a significant reason for overnight stays is the trauma requiring recovery, and eliminating trauma is a major goal and advantage of minimally invasive technologies (e.g., especially the NOTES technology platform). A wide range of other technologies (e.g., gamma knife, minimally invasive surgery/intervention, etc.) across multiple categories (device, biotech, pharma) will also have emerged and succeeded in the market by producing therapeutic benefit while minimizing or eliminating collateral damage.

  • Information technology will radically improve patient management. Very sophisticated electronic patient records will dramatically improve patient care via reduction of contraindications, predictive systems to proactively manage disease and disease risk, and greatly improve the decision-making of physicians tasked with diagnosing and treating patients.There are few technical hurdles to the advancement of information technology in medicine, but even in 2035, infotech is very likely to still be facing real hurdles in its use as a result of the reluctance in healthcare to give up legacy systems and the inertia against change, despite the benefits. [Editor’s note: Before AI and other systems will truly have an impact, IT and its policy for healthcare in the next 10 years will solve the problem of health data residing inertly behind walls that hinder efficient use of the rich, patient-specific knowledge that physicians and healthcare systems might use to improve the quality and cost of care.]
  • Personalized medicine. Perfect matches between a condition and its treatment are the goal of personalized medicine, since patient-to-patient variation can reduce the efficacy of off-the-shelf treatment. The thinking behind gender-specific joint replacement has led to custom-printed 3D implants. The use of personalized medicine will also be manifested by testing to reveal potential emerging diseases or conditions, whose symptoms may be ameliorated or prevented by intervention before onset.
  • Systems biology will underlie the biology of most future medical advances in the next 20 years. Systems biology is a discipline focused on an integrated understanding of cell biology, physiology, genetics, chemistry, and a wide range of other individual medical and scientific disciplines. It represents an implicit recognition of an organism as an embodiment of multiple, interdependent organ systems and its processes, such that both pathology and wellness are understood from the perspective of the sum total of both the problem and the impact of possible solutions.This orientation will be intrinsic to the development of medical technologies, and will increasingly be represented by clinical trials that throw a much wider and longer-term net around relevant data, staff expertise encompassing more medical/scientific disciplines, and unforeseen solutions that present themselves as a result of this approach.Other technologies being developed aggressively now will have an impact over the next twenty years, including medical/surgical robots (or even biobots), neurotechnologies to diagnose, monitor, and treat a wide range of conditions (e.g., spinal cord injury, Alzheimer’s, Parkinson’s etc.).

The breadth and depth of advances in medicine over the next 20 years will be extraordinary, since many doors have been recently opened as a result of advances in genetics, cell biology, materials science, systems biology and others — with the collective advances further stimulating both learning and new product development. 


See Reports:

Report #290, “Worldwide Markets for Medical and Surgical Sealants, Glues, and Hemostats, 2015-2022.”

Report #S254, “Wound Management to 2026.”

The global dynamics of cardiovascular surgical and interventional procedures

This is an excerpt from Report #C500, “Cardiovascular Procedures to 2022.”

Cardiovascular Procedures in 2016

• Coronary artery bypass graft (CABG) surgery;
 • Coronary angioplasty and stenting;
 • Lower extremity arterial bypass surgery;
  • Percutaneous transluminal angioplasty (PTA) with and without bare metal and drug-eluting stenting;
  • Peripheral drug-coated balloon angioplasty;
  • Peripheral atherectomy;
  • Surgical and endovascular aortic aneurysm repair;
  • Vena cava filter placement
  • Endovenous ablation;
  • Mechanical venous thrombectomy;
  • Venous angioplasty and stenting;
  • Carotid endarterectomy;
  • Carotid artery stenting;
  • Cerebral thrombectomy;
  • Cerebral aneurysm and AVM surgical clipping;
  • Cerebral aneurysm and AVM coiling & flow diversion;
  • Left Atrial Appendage closure;
  • Heart valve repair and replacement surgery;
  • Transcatheter valve repair and replacement;
  • Congenital heart defect repair;
  • Percutaneous and surgical placement of temporary and permanent mechanical cardiac support devices;
  • Pacemaker implantation;
  • Implantable cardioverter defibrillator placement;
  • Cardiac resynchronization therapy device placement;
  • Standard SVT & VT ablation; and
  • Transcatheter AFib ablation

In 2016, the cumulative worldwide volume of the most prevalent cardiac surgeries and other  cardiovascular procedures (at right) is projected to approach 15.05 million surgical and transcatheter interventions. This will include:

  • in coronart artery disease, roughly 4.73 million coronary revascularization procedures via coronary artery bypass graft (CABG) and percutaneous coronary intervention (PCI) or about 31.4% of the total),
  • close to 4 million percutaneous and surgical peripheral artery revascularization procedures (or 26.5% of the total);
  • about 2.12 million cardiac rhythm management procedures via implantable pulse generator placement and arrhythmia ablation (or 14.1% of the total);
  • over 1.65 million  chronic venous insufficiency, deep vein thrombosis, and pulmonary embolism targeting venous interventions (representing 11.0% of the total);
  • more than 992 thousand surgical and transcatheter heart defect repairs and  valve replacement or valve repair  (or 6.6% of the total);
  • close to 931 thousand acute stroke prophylaxis and treatment procedures (contributing 6.2% of the total);
  • over 374 thousand abdominal and thoracic aortic aneurysm endovascular and surgical repairs (or 2.5% of the total); and
  • almost 254 thousand placements of temporary and permanent mechanical cardiac support devices in bridge to recovery, bridge to transplant, and destination therapy indications (accounting for about 1.7% of total procedure volume).

During the period 2016 to 2022, the total worldwide volume of covered cardiovascular procedures is forecast to expand on average by 3.7% per annum to over 18.73 million corresponding surgeries and transcatheter interventions in the year 2022. The largest absolute gains can be expected in peripheral arterial interventions (thanks to explosive expansion in utilization of drug-coated balloons in all market geographies), followed by coronary revascularization (supported by continued strong growth in Chinese and Indian PCI utilization) and endovascular venous interventions (driven by grossly underserved patient caseloads within the same Chinese and Indian market geography).

The latter (venous) indications are also expected to register the fastest (5.1%) relative procedural growth, followed by peripheral revascularization (with 4.0% average annual advances) and aortic aneurysm repair (projected to show a 3.6% average annual expansion).

http://mediligence.com/c500/

Geographically, Asian-Pacific (APAC) market geography accounts for slightly larger share of the global CVD procedure volume than the U.S. (29.5% vs 29,3% of the total), followed by the largest Western European states (with 23.9%) and ROW geographies (with 17.3%). Because of the faster growth in all covered categories of CVD procedures, the share of APAC can be expected to increase to 33.5% of the total by the year 2022, mostly at the expense of the U.S. and Western Europe.

However, in relative per capita terms, covered APAC territories (e.g., China and India) are continuing to lag far behind developed Western states in utilization rates of therapeutic CVD interventions with roughly 1.57 procedures per million of population performed in 2015 for APAC region versus about 13.4 and 12.3 CVD interventions done per million of population in the U.S. and largest Western European countries.


Report #C500: “Global Dynamics of Surgical and Interventional Cardiovascular Procedures, 2015-2022.” Request excerpts.

This report may be purchased for immediate download at link.

Cardiovascular procedure volume growth (interventional and surgical)

Cardiovascular surgical and interventional procedures are performed to treat conditions causing inadequate blood flow and supply of oxygen and nutrients to organs and tissues of the body. These conditions include the obstruction or deformation of arterial and venous pathways, distortion in the electrical conducting and pacing activity of the heart, and impaired pumping function of the heart muscle, or some combination of circulatory, cardiac rhythm, and myocardial disorders. Specifically, these procedures are:

  • Coronary artery bypass graft (CABG) surgery;
  • Coronary angioplasty and stenting;
  • Lower extremity arterial bypass surgery;
  • Percutaneous transluminal angioplasty (PTA) with and without bare metal and drug-eluting stenting;
  • Peripheral drug-coated balloon angioplasty;
  • Peripheral atherectomy;
  • Surgical and endovascular aortic aneurysm repair;
  • Vena cava filter placement
  • Endovenous ablation;
  • Mechanical venous thrombectomy;
  • Venous angioplasty and stenting;
  • Carotid endarterectomy;
  • Carotid artery stenting;
  • Cerebral thrombectomy;
  • Cerebral aneurysm and AVM surgical clipping;
  • Cerebral aneurysm and AVM coiling & flow diversion;
  • Left Atrial Appendage closure;
  • Heart valve repair and replacement surgery;
  • Transcatheter valve repair and replacement;
  • Congenital heart defect repair;
  • Percutaneous and surgical placement of temporary and permanent mechanical cardiac support devices;
  • Pacemaker implantation;
  • Implantable cardioverter defibrillator placement;
  • Cardiac resynchronization therapy device placement;
  • Standard SVT & VT ablation; and
  • Transcatheter AFib ablation

For 2016 to 2022, the total worldwide volume of these cardiovascular procedures is forecast to expand on average by 3.7% per year to over 18.73 million corresponding surgeries and transcatheter interventions in the year 2022. The largest absolute gains can be expected in peripheral arterial interventions (thanks to explosive expansion in utilization of drug-coated balloons in all market geographies), followed by coronary revascularization (supported by continued strong growth in Chinese and Indian PCI utilization) and endovascular venous interventions (driven by grossly underserved patient caseloads within the same Chinese and Indian market geography).

Venous indications are also expected to register the fastest (5.1%) relative procedural growth, followed by peripheral revascularization (with 4.0% average annual advances) and aortic aneurysm repair (projected to show a 3.6% average annual expansion).

Source: MedMarket Diligence, LLC; “Global Dynamics of Surgical and Interventional Cardiovascular Procedures, 2015-2022,” (Report #C500).

Geographically, Asian-Pacific (APAC) market geography accounts for slightly larger share of the global CVD procedure volume than the U.S. (29.5% vs 29,3% of the total), followed by the largest Western European states (with 23.9%) and ROW geographies (with 17.3%). Because of the faster growth in all covered categories of CVD procedures, the share of APAC can be expected to increase to 33.5% of the total by the year 2022, mostly at the expense of the U.S. and Western Europe.

However, in relative per capita terms, covered APAC territories (e.g., China and India) are continuing to lag far behind developed Western states in utilization rates of therapeutic CVD interventions with roughly 1.57 procedures per million of population performed in 2015 for APAC region versus about 13.4 and 12.3 CVD interventions done per million of population in the U.S. and largest Western European countries.

Source: MedMarket Diligence, LLC; “Global Dynamics of Surgical and Interventional Cardiovascular Procedures, 2015-2022,” (Report #C500).


Global Cardiovascular Procedures report #C500 details the current and projected surgical and interventional therapeutic procedures commonly used in the management of acute and chronic conditions affecting myocardium and vascular system.

Interventional and Surgical Cardiovascular Procedure Volumes

Cardiovascular diseases (CVDs) are a variety of acute and chronic medical conditions associated with an inability of the cardiovascular system to sustain an adequate blood flow and supply of oxygen and nutrients to organs and tissues of the body. The CVD conditions may be manifested by the obstruction or deformation of arterial and venous pathways, distortion in the electrical conducting and pacing activity of the heart, and impaired pumping function of the heart muscle, or some combination of circulatory, cardiac rhythm, and myocardial disorders.

These diseases are treated via the following surgical and interventional procedures:

  • Coronary artery bypass graft (CABG) surgery;
  • Coronary angioplasty and stenting;
  • Lower extremity arterial bypass surgery;
  • Percutaneous transluminal angioplasty (PTA) with and without bare metal and drug-eluting stenting;
  • Peripheral drug-coated balloon angioplasty;
  • Peripheral atherectomy;
  • Surgical and endovascular aortic aneurysm repair;
  • Vena cava filter placement
  • Endovenous ablation;
  • Mechanical venous thrombectomy;
  • Venous angioplasty and stenting;
  • Carotid endarterectomy;
  • Carotid artery stenting;
  • Cerebral thrombectomy;
  • Cerebral aneurysm and AVM surgical clipping;
  • Cerebral aneurysm and AVM coiling & flow diversion;
  • Left Atrial Appendage closure;
  • Heart valve repair and replacement surgery;
  • Transcatheter valve repair and replacement;
  • Congenital heart defect repair;
  • Percutaneous and surgical placement of temporary and permanent mechanical cardiac support devices;
  • Pacemaker implantation;
  • Implantable cardioverter defibrillator placement;
  • Cardiac resynchronization therapy device placement;
  • Standard SVT & VT ablation; and
  • Transcatheter AFib ablation

In 2016, the cumulative worldwide volume of these procedures is projected to approach 15.05 million surgical and transcatheter interventions. This will include:

  • roughly 4.73 million coronary revascularization procedures via CABG and PCI (or about 31.4% of the total),
  • close to 4 million percutaneous and surgical peripheral artery revascularization procedures (or 26.5% of the total);
  • about 2.12 million cardiac rhythm management procedures via implantable pulse generator placement and arrhythmia ablation (or 14.1% of the total);
  • over 1.65 million CVI, DVT, and PE targeting venous interventions (representing 11.0% of the total);
  • more than 992 thousand surgical and transcatheter heart defect repairs and valvular interventions (or 6.6% of the total);
  • close to 931 thousand acute stroke prophylaxis and treatment procedures (contributing 6.2% of the total);
  • over 374 thousand abdominal and thoracic aortic aneurysm endovascular and surgical repairs (or 2.5% of the total); and
  • almost 254 thousand placements of temporary and permanent mechanical cardiac support devices in bridge to recovery, bridge to transplant, and destination therapy indications (accounting for about 1.7% of total procedure volume).

Below is illustrated the overall global growth for each of the major categories of procedures through 2022.

Source: MedMarket Diligence, LLC; Report #C500.  (Full report available online.)

There is considerable variation in the growth of cardiovascular procedures globally, but most growth is coming out of Asia/Pacific. For example, within the area of venous interventions, the growth in the use of endovenous ablation for chronic venous insufficiency is markedly higher in Asia/Pacific than in other regions, though the U.S. will remain the largest volume of these procedures.

Source: MedMarket Diligence, LLC; Report #C500.  (Full report available online.)


“Global Dynamics of Surgical and Interventional Cardiovascular Procedures, 2015-2022” (Report #C500), published August 2016. See description, table of contents, list of exhibits at link. Available for purchase and download from link.

Forgotten Opportunities: Early Stage Biotech and Medtech Investment

Due to the uncertainty in the development, clinical testing, and regulatory approval of both biotech and medical technologies, which increasingly have to be viewed with the same competitive lens, investors have over the past few years shied away from seed stage or Series A stage company investment in favor of those nearer to market introduction. However, with the advent of a great number of new technologies and advances in the underlying science, there is enormous opportunity to identify companies and emerging sectors arising from these advances. The problem in identifying realistically promising companies is that it must be done so without falling prey to the bad investment practices in the past that ensued from a poor understanding of the technologies and their remaining commercial hurdles. Without careful consideration of remaining scientific development needed, the product’s target market, its competitors, and the sum total of the company’s capabilities to commercialize these technologies, investment in these areas will fall short of investment objectives or fail them outright.

While any of these considerations have the capacity to preempt a successful market introduction, a failure to understand the science behind the product and its remaining development hurdles to commercialization is likely to be the biggest cause of failure.

“We’ve already had one glaring example of a company, and its investors, learning the hard way that health and science advisors are important: Theranos.” (link)

Venture Capital has backed away from early stage investment

Earlier stage investment, with its higher risk, has higher potential reward, so there is a big need for more effective evaluation of potential early stage investments in order to (1) seize these opportunities that will otherwise potentially be lost with the shift to later stage fundings, (2) sort out those companies/technologies with overwhelming commercialization hurdles from those that will profitably tap an opportunity, and (3) gain the value of these opportunities before the innovation appreciates in value, driving up the price of the investment.

The Biotech Bubble

Biotech in the 1980s was enamored with companies pursuing “magic bullets” — technologies that had the potential to cure cancer or heart disease or other conditions with large, untapped or under-treated populations. With few exceptions, these all-in-one-basket efforts were only able achieve a measure of humility in the VCs who had poured volumes of money into them.

Here was evidenced a fundamental problem with biotech at a time when true scientific milestones were being reached, including successes in mapping the human genome: Landmark scientific milestones do not equate with commercial success.

As a result, money fled from biotech as few products could make it to market due to persistent development and FDA hurdles. By the late 1980s, many biotechs saw three quarters of their value disappear.

A Renewed Bubble?

The status of biomedical science and technology, with multiple synergistic developments, will lead to wild speculation and investment, potentially leading to yet another investment bubble. However, there will be advances that can point to real timelines for market introduction that will support investment.

Recent advances, developments and trends supporting emerging therapeutics

  1. Stem cells. A double-edged sword in that these do represent some the biggest therapeutics that will emerge, yet caution is advised since the mechanisms to control stem cells are not always sufficient to prevent their nasty tendency to become carcinogenic.
  2. Drug discovery models, such as using human “organoids” and other cell-based models to test or screen new drugs.
  3. Systems to accelerate the rapid evaluation of hundreds, perhaps, thousands of potential drugs before moving to animal models or preclinicals.
    1. Machine-learning algorithms
    2. Cell/tissue/organ models
    3. Meta-analysis, the practice of analyzing multiple, independently produced clinical data to draw conclusions from the broader dataset.
  4. Cross-discipline science
    1. cell biologists, immunologists, molecular biologists and others have a better understanding of pathology and therapeutics as a result of information sharing; plus BIG DATA (e.g., as part of the “Cancer Moonshot”). Thought leaders have called for collection and harnessing of patient data on a large scale and centralized for use in evaluating treatments for specific patients and cancer types.
    2. Artificial intelligence applied to diagnosis and prescribed therapeutics (e.g., IBM Watson).
    3. Examples of resulting therapies, at a minimum, include multimodal treatment – e.g., radiotherapy and immunotherapy – but more often may be represented in considerably more backend research and testing to identify and develop products with greater specificity, greater efficacy, and lowered risk of complications.
  5. Materials science developments, selected examples:
    1. Scaffolds in tissue engineering
    2. Microgels
    3. Graphene
    4. Polyhedral boranes
    5. Nanometric imprinting on fiber
    6. Knitted muscles to provide power link
    7. 3-D printed skin and more complex organs to come
    8. Orthopedic scaffolds made from electrospun nanofibers
  6. CAR-T (chimeric antigen receptor T cell therapy)
  7. CRISPR/Cas-9. Gene editing
    1. Removal, insertion of individual genes responsible for disease
    2. Potential use for creating chimeras of human and other (e.g., pig) species in order to, for example, use pigs for growing human organs for transplant.
  8. Smart devices: smart biopsy needles, surgical probes to detect cancer margins, artificial pancreas. Devices using information

 

We sum this up with these prerequisites for investment:

Prerequisites for Early Stage Med/Bio Investment

  1. A fully understood and managed gap between scientific advance and commercial reality.
    1. Investment must be tied to specific steps (prototyping, preclinicals, clinicals, physician training, etc.).
  2. A management team qualified in commercializing medtech or biotech products.
    1. CEOs (and/or Chief Medical Officers, Chief Scientific Officers) with medical science backgrounds (MD, PhD) favored over CPAs or even JDs.
  3. Reimbursement strategy pursued as something more than an afterthought
  4. Technology development in sync with end-user acceptance and training to leverage the benefits:
    1. Easier to use
    2. Fewer complications
    3. Attractive physician revenue streams
  5. Broad competitive advantage pursued:
    1. Product benefits must stand up against all competition, irrespective of technology type (devices competing with drugs, biotech).
    2. Benefits of reducing the cost of care for an existing patient population are paramount.
    3. Competitive advantage must consider the trend in technology development to avoid being disrupted by other products soon to reach the market.
  6. Predefined exit strategy; selected examples:
    1. Positioning to add innovation to a mid-cap or large-cap medtech or biotech as acquirers.
    2. Development of platform technologies for licensing or sale.
    3. IPO

 

Future investments are likely to track the historical focus on specific diseases and conditions:

Source: MedMarket Diligence, LLC and Emerging Therapeutic Company Investment and Deal Trends; Biotechnology Innovation Organization.


MedMarket Diligence, mediligence.com, tracks medical and biotechnology development to provide meaningful insights for manufacturers, investors, and other stakeholders.

The best medtech investment opportunities

In reviewing patents, fundings, technology development trends, market development, and other hard data sources, we feel these are some of the strongest areas for investment in not only the medical device side of medtech, but also the broader biomedical technology arena:

  • Materials technologies
    • graphene
    • bioresorbables
    • biosensors
    • polymers
    • bioadhesives
  • Cell therapy and tissue engineering
    • cell-based treatments (diabetes, spinal cord injury, traumatic brain injury)
    • extracellular matrices in soft tissue repair and regeneration
  • Nanotechnology (subject of forthcoming report)
    • nano coatings
    • nano- and micromedical technologies for localized drug delivery
    • nanoparticles
  • 3D printing
    • prototype development
    • patient-specific implants
  • Minimally- and non-invasive technologies
    • transcatheter alternatives to surgery
    • NOTES (natural orifice transluminal endoscopic surgery)
  • Diabetes non-invasive glucose testing
  • Intraoperative surgical guidance
    • Cancer probes (e.g., fluorescent or optical coherence tomography, frozen section, cytologic imprint analysis, ultrasound, micro-computed tomography, near-infrared imaging, and spectroscopy)
  • neurostimulation and neuromodulation
  • point-of-care diagnostics
  • point-of-care imaging
  • AI-enhanced devices

In addition, there are many areas in healthcare in which there is much untapped demand with problems that, so far, seem to have eluded medtech solutions. These include infection control (Zika, MRSA, TB, nosocomial infections, etc.), chronic wound treatment (including decubitus/stasis/diabetic ulcers), type 2 diabetes and obesity.

 

Coronary revascularization options evolve

The number of options that are in use or development for coronary revascularization or other treatment for ischemic heart disease is extraordinary. Given the mortality associated with coronary artery disease, it is unsurprising that it has been the focus of so much development.

Below are the options that have evolved for treatment of ischemic heart disease, inclusive of surgical, interventional, and other medical approaches.

Coronary Revascularization and Other
Ischemic Heart Treatment Options

Source: MedMarket Diligence, LLC

See also “Global Dynamics of Surgical and Interventional Cardiovascular Procedures, 2015-2022”, report #C500. Order online.

Peripheral Stenting Worldwide: Arterial, Venous, BMS, DES, AAA, TAA

First introduced about two decades ago as a bailout technique for suboptimal or failed iliac angioplasty, peripheral vascular stenting gradually emerged as a valuable and versatile tool for a variety of primary and adjuvant applications outside the domain of coronary and cerebral vasculature.  Today, peripheral vascular stenting techniques are commonly employed in the management of the most prevalent occlusive circulatory disorders and other pathologies affecting the abdominal and thoracic aortic tree and lower extremity arterial bed. Stents are also increasingly used in the management of the debilitating conditions like venous outflow obstruction associated with deep venous thrombosis and chronic venous insufficiency.

Notwithstanding a relative maturity of the core technology platforms and somewhat problematic opportunities for conversion to value-adding peripheral drug-eluting systems, peripheral vascular stenting appears to have a significant room for qualitative and quantitative growth both in established and emerging peripheral indications.

A panoply of stenting systems are available for the management of occlusive disorders and other pathologies affecting peripheral arterial and venous vasculature. Systems include lower extremity bare metal and drug-eluting stents for treatment of symptomatic PAD and critical limb ischemia resulting from iliac, femoropopliteal and infrapopliteal occlusive disease; stent-grafting devices used in endovascular repair of abdominal and thoracic aortic aneurysms; as well as a subset of indication-specific and multipurpose peripheral stents used in recanalization of iliofemoral and iliocaval occlusions resulting in CVI.

In 2015, these peripheral stenting systems were employed in approximately 1.565 million revascularization procedures worldwide, of which the lower extremity arterial stenting accounted for almost 1.252 million interventions (or 80.9%), followed by AAA and TAA endovascular repairs with 162.4 thousand interventions (or 10.5%) and peripheral venous stenting used in an estimated 132.6 thousand patients (or 8.6% of the total).

The U.S. clinical practices performed almost 528 thousand covered peripheral arterial and venous procedures (or 34.1% of the worldwide total), followed by the largest Western European states with over 511 thousand interventions (or 33.1%), major Asian-Pacific states with close to 377 thousand interventions (or 24.4%), and the rest-of-the-world with about 131 thousand peripheral stent-based interventions (or 8.4%).

Below is illustrated the global market for peripheral stenting by region in 2016 and by segment from 2014 to 2020.

Source: MedMarket Diligence, LLC; Report #V201. Available online.

 

Source: MedMarket Diligence, LLC; Report #V201. Available online.