MedMarket Future: Developments in Growth Technologies

Proliferation of graphene applications

The nature of graphene’s structure and its resulting traits are responsible for a tremendous burst of research focused on applications.

  • Find cancer cells. Research at the University of Illinois at Chicago showed that interfacing brain cells on the surface of a graphene sheet allows the ability to differentiate a single hyperactive cancerous cell from a normal cell. This represents a noninvasive technique for the early detection of cancer.
  • Graphene sheets capture cells efficiently. In research similar to that U. Illinois, modification of the graphene sheet by mild heating enables annealing of specific targets/analytes on the sheet which then can be tested. This, too, offers noninvasive diagnostics.
  • Contact lens coated with graphene. While the value of the development is yet to be seen, researchers in Korea have learned that contact lenses coated with graphene are able to shield wearers’ eyes from electromagnetic radiation and dehydration.
  • Cheaply mass-producing graphene using soybeans. A real hurdle to graphene’s widespread use in a variety of applications is the cost to mass produce it, but Australia’s CSIRO has shown that an ambient air process to produce graphene from soybean oil, which is likely to accelerate graphenes’ development for commercial use.

Materials

Advanced materials development teams globally are spinning out new materials that have highly specialized features, with the ability to be manufactured under tight control.

  • 3D manufacturing leads to highly complex, bio-like materials. With applications across many industries using “any material that can be crushed into nanoparticles”, University of Washington research has demonstrated the ability to 3D engineer complex structures, including for use as biological scaffolds.
  • Hydrogels and woven fiber fabric. Hokkaido University researchers have produced woven polyampholyte (PA) gels reinforced with glass fiber. Materials made this way have the structural and dynamic features to make them amenable for use in artificial ligaments and tendons.
  • Sound-shaping metamaterial. Research teams at the Universities of Sussex and Bristol have developed acoustic metamaterials capable of creating shaped sound waves, a development that will have a potentially big impact on medical imaging.

Organ-on-a-chip

In vitro testing models that more accurately reflect biological systems for drug testing and development will facilitate clinical diagnostics and clinical research.

  • Stem cells derived neuronal networks grown on a chip. Scientists at the University of Bern have developed an in vitro stem cell-based bioassay grown on multi-electrode arrays capable of detecting the biological activity of Clostridium botulinum neurotoxins.
  • Used for mimicking heart’s biomechanical properties. At Vanderbilt University, scientists have developed an organ-on-a-chip configuration that mimics the heart’s biomechanical properties. This will enable drug testing to gauge impact on heart function.
  • Used for offering insights on premature aging, vascular disease. Brigham and Women’s Hospital has developed organ-on-a-chip model designed to study progeria (Hutchinson-Gilford progeria syndrome), which primarily affects vascular cells, making this an affective method for the first time to simultaneously study vascular diseases and aging.

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.

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.

Cardiovascular Surgical and Interventional Procedures Worldwide, 2015-2022

In 2016, the cumulative worldwide volume of the the following CVD procedures is projected to approach 15.05 million surgical and transcatheter interventions:

  • 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).

screen-shot-2016-11-07-at-7-26-38-am

CABG: Coronary artery bypass graft; PCI: Percutaneous coronary intervention; AAA: Abdominal aortic aneurysm; TAA: Thoracic abdominal aneurysm; CVI: Chronic venous insufficiency; DVT: Deep vein thrombosis; PE: Pulmonary embolectomy.

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

Cerebral thrombectomy procedures worldwide

In 2014, approximately 33.7 thousand cerebral thrombectomy procedures were performed worldwide, of which United States and largest European states accounted for roughly 46% and 37%, largest Asian states contributed 10.4% and the rest of the world added remaining 6.5%.

The 2014 global cerebral thrombectomy system sales were estimated at approximately $166 million, of which the United States accounted for about $79.1 million (or ~47.7%), followed by the largest Western European states with $59.4 million (or 35.8%), major Asian states with $17 million (or 10.2%) and the rest-of-the-world with $10.5 million (or 6.3% of the total).

In the view of the industry insiders and practicing neurointerventional radiologists, relatively modest volume of life-saving cerebral thrombectomy procedures and corresponding product sales appear to reflect still insufficient body of favorable clinical data and inhibiting impact of the published dubious findings from the major IMS-III study.

The latter compared first-generation cerebral thrombectomy techniques with standard medical (and tPA) therapy and asserted that endovascular clot retrieval interventions did not result in visible improvement in patient outcomes. The cited conclusions clearly contradict results of numerous randomized trials with available second-generation cerebral revascularization systems, which appear to documented superiority of the latter system in management of acute ischemic stroke caseloads.

It is generally assumed that the situation with end-user adoption is likely to improve dramatically in two-three years from now, when results of the ongoing major U.S. and international trials with novel cerebral thrombectomy devices become available.

Based on these assumptions, the cumulative worldwide volume of cerebral thrombectomy procedures is projected to experience accelerated growth to the end of the forecast period resulting in 10.8% overall average annual expansion of corresponding interventions in the forthcoming five years to an estimated 56.2 thousand total procedures worldwide in 2019.

screen-shot-2016-10-17-at-7-14-32-am
From: “Emerging Global Market for Neurointerventional Technologies in Stroke, 2014-2019”, Report #C310.

The worldwide market for cerebral clot retrieval systems is forecast to grow at a slightly slower pace expanding on average 10.1% per annum to about $268.4 million in the year 2019. Price pressure will keep sales growth lower than procedure volume gains.

The largest absolute dollar gains can be expected in the U.S. market (which is projected to add $55.9 million in corresponding device revenues), followed by the West European marketplace (+ $30.6 million), major Asian state business (+ $11.2 million) and the rest-of-the-world (+ $4.7 million).

Requirements for acceptance of new peripheral stents in clinical practice

Stents are implantable devices designed as endoluminal scaffolds to maintain patency following recanalization of occluded or structurally compromised vascular (and non-vascular) circulatory conduits that enable energy supply and metabolic exchange in various organs and tissues of the human body. Palliative stenting has been routinely used for decades in the management of acute and chronic obstructions of gastro-intestinal, pulmonary and urinary tracts secondary to benign or malignant neoplasms or other cite-specific or systemic pathologies. However, a real explosion in utilization of stents was triggered in the early 1990s by the advent of vascular stenting devices, which allowed radically improved clinical outcomes of balloon angioplasty and supported its emergence as the first choice treatment modality for occlusive peripheral and coronary artery disease (PAD and CAD). By the end of 2014, more than three quarters of patients with acute and chronic arterial occlusions warranting intervention were referred for angioplasty-based therapy, which entailed placement of stenting devices in over 80% of commonly performed peripheral revascularization procedures.

To be accepted in clinical practices, stenting implants should satisfy a number of general and application-specific requirements relating to device biocompatibility, functional performance, and end-user and patient friendliness which are summarized in the exhibit below. In very general terms, stenting device biocompatibility refers to minimization of hostile immune responses (and other local and systemic adverse reactions) that are inevitably triggered by a direct contact of any implantable medical device with living tissues and bodily fluids in situ. For understandable reasons, biocompatibility depends primarily on the implant surface material, including such characteristics as chemical inertness and stability, corrosion resistance, etc. The stenting device biocompatibility can also be effected somewhat by the duration of its presence in situ and specifics of the deployment site and occlusion causing pathology.

The stent’s functional performance (or ability to maintain adequate scaffolding support and lumen patency for a desired period of time) represents a complex function of the device design/architecture and the relative static and dynamic strength of its base material. The chosen stenting device’s architecture and structural material predetermine it radial strength, longitudinal flexibility, conformability and foreshortening, as well as relative lesion coverage, fatigue and kinking resistance, circulatory flow obstruction, etc.

Finally, the stent’s end-user and patient friendliness are predicated both by the design concept of the delivery system and stenting device and refers to procedural convenience, predictability, safety, morbidity, availability of bail-out options, etc. The commonly acknowledged stenting system characteristics relating to the end-user/patient friendliness include low profile, flexibility, traceability, high radiopacity, compatibility with established transcatheter tools and techniques, ease of use and short learning curve, simplicity of retrieval in case of procedural failure, possibility of emergent /elective conversion to surgery, etc.

Selected Biomedical, Clinical and Technical Requirements
for Stenting Implants

screen-shot-2016-10-04-at-2-36-22-pm

Source: MedMarket Diligence, LLC; Report #V201.

Coronary and venous interventions show inevitable Asia/Pacific dominance

Coronary revascularization, whether by bypass graft or percutaneous coronary intervention, drives an enormous amount of medtech business. Angioplasty catheters, guidewires, and the plethora of devices in cardiothoracic surgery represent many millions in sales annually. Manufacturers pursuing growth in these areas will see big, but slowing growth rates in the U.S., while markets in Asia/Pacific reflect the growing demand for cardio technologies. Already, these markets are surpassing western markets:

screen-shot-2016-10-03-at-2-20-47-pm

Source: Report #C500.

While coronary applications have a long history, venous interventions have less, and procedure data shows that patient populations have not been fully tapped in any geographic region. Already, Asia/Pacific markets would appear to be on course to eclipse western markets, but not until after 2022, and will eclipse Western Europe markets before challenging the U.S.

screen-shot-2016-10-03-at-2-20-38-pm

Source: Report #C500.

Coronary and Peripheral Vascular Dominate Global Cardiovascular Procedure Volumes

In 2016, the cumulative worldwide volume of the cardiovascular device 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).

screen-shot-2016-09-28-at-11-05-28-am

Source: Global Dynamics of Surgical and Interventional Cardiovascular Procedures, 2015-2022.