Acceleration of Adoption of High Complexity Precision Diagnostics in Oncology by Global Public Healthcare Systems: A Case Study of Europe and Beyond

Iain D. Miller, Ph.D.

Précis

Clinical impact in the “post-genome” years following the 2003 publication of the first human genome sequence map was much slower than many anticipated. For a host of technical and business reasons, commercial gains were slow to materialize and largely confined to US-centric markets.More recently, bodies like NICE in the UK have moved ahead in terms of HTA methodology and developing the political will to tackle the difficult, underlying, quality of life value questions.In this article, we will consider both prognostic and predictive scenarios, with their distinct clinical value propositions and business model options. We focus on European markets as a case study and make the argument to extend the model to global markets.

Introduction:  Precision Medicine Adoption

Recent years have seen significant progress made in the adoption of precision medicine and high complexity testsby public healthcare systems. Prognostic testing for early stage breast cancer and next-generation sequencing (NGS) for advanced cancer are selected as exemplar application areas for analysis.This article reviews the public sector adoption in global marketsand the associated success factors for the precision medicine industry.

The First Generation

Early precision medicine testing generally involved assaying the mutational status or expression of oncogenes, as shown in the Table 1.While results from these assays provided high negative predictive value for patient selection, they generally proved less effective at identifying durable responders1. Further, such single gene testing provided little information on the evolution of resistance.

First Generation Precision Medicine
Clinical Setting (at launch) Gene / Biomarker Therapy
Breast Cancer ER/PR Tamoxifen
Breast Cancer HER2 HerceptinTM
Chronic Myelogenous Leukemia (CML) BCR-ABL GleevecTM
Lung Cancer EGFR IressaTM/TarcevaTM
Colorectal Cancer KRAS VectibixTM / PanitumumabTM

Table 1. Snapshot of first-generation precision medicinegene biomarkers that specify therapies for disease conditions.

Nevertheless, the new post-2000 generation of targeted therapies, led by HerceptinTM for breast cancer, GleevecTM for chronic myelogenous leukemia (CML) and IressaTM/TarcevaTM for lung cancer, represented a step change in the options available for many patients, and healthcare systems pivoted to provide molecular diagnostic selection as part of the initial patient workup. Notable examples of clinical success for targeted intervention have included tripling the percent of imatinib-treated CML patients (22% to 67%) who are expected to survive for five years2.  Regulatory approvals for such targeted therapies continue to increase year over year; the FDA approved 25 molecularly targeted indications in 2018, including 10 new molecular entities and 15 expanded indications of previously approved products, compared to 19 approvals in 20173.

From a US regulatory and market access standpoint, FDA came to require concurrent New Drug Application – Premarket Approval (NDA/PMA) filings, whilepublic payors (including the Centers for Medicare and Medicaid Services) andprivate payorsaccommodated associated test coveragevia previously coded technical procedures (Current Procedural Terminology (CPT) codes).  Outside the US, where reimbursement systems were often slower to adapt, precision testing coverage was often delayed and alternative (“pharma-pays”) reimbursement models emerged in some geographies4. Over time, most advanced western public healthcare systems have evolved to incorporate monogenic molecular testing as part of the care pathway for targeted therapies, and new Proprietary Laboratory Analysis (PLA) codes5 have now emerged in the US to bring specificity to provider test requisitions.

More recently, this single-marker molecular test paradigm has extended to immuno-oncology, with the widespread use of PD-L1 testing for checkpoint inhibitor therapies such as KeytrudaTM, OpdivoTM, TecentriqTM and BavencioTM.  Following the launch of this class of drug, diagnostics developers introduced a host of companion and complementary diagnosticsfor patient .  In the US and elsewhere,complementary tests may be“substantially equivalent” to companion tests, however, the USFDAmakes a distinction with the designation “companion”forassays that generate data validated to beessential for the safe and effective use of a corresponding drug or biological product.

[Definitions to be placed an INSET (for Journal layout)

Distinctions between “complementary” and “companion” diagnostics:

Complementary Diagnostics: may inform on improving the benefit/risk ratio without restricting drug access

Companion Diagnostics: essential for the safe and effective use of a corresponding drug or biological product

See: Current Status of Companion and Complementary Diagnostics: Strategic Considerations for Development and Launch, H Scheerens et al., Clin Transl Sci. 2017 Mar; 10(2): 84–92, https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5355969/]

Emergence of Next-generation Precision Medicine

As noted, prevailing single biomarker companion and complementary tests have historically been best suitedto ruling out candidates for therapy.In recent years, “next generation” predictive tests have evolved which attempt to deliver a step change in value by assaying multiple such target markers simultaneously to assess genomic instability, tumour mutational burden and broader host profile. Further, drug labels have evolved to include biomarker defined diseases, with early examples including PembrolizumabTM7 and VitrakviTM8. Other multi-marker tests, directed towards prognosing disease, have been developed to inform whether a patient would likely respond to, or benefit at all from, less selective chemotherapies. As with forerunner single-gene tests, earliest adoption has generally occurred in the United States.

Events picked up speed starting 2015-2016 when the Obama Administration established the Precision Medicine Initiative (PMI).PMI funding through NIH and other agencies served as an early accelerant for precision medicine programs.  In parallel, CMSfurther accelerated uptake with coverage determinations to reimburse single-gene IVD and LDT tests.

We propose that the real progress of precision medicine in clinics may best be measured by how public healthcare systems and payors outside the US have adopted high-complexity, high-precision predictive and prognostic tests.  As US companies set up end-to-end ecosystems, retired risks, and developed business, regulatory, and technical models, the markets, in turn, expressed their confidence by rewarding those who met their needs.

Experience gained over time paved the path for complex tests in sponsor pipelines worldwide. Major developed western public healthcare systems followed with the launch of next generation tests.  And while such tests have become a standard of care in the US, bodies like NICE in the UK have moved ahead in terms of HTA methodology and developing the political will to tackle the difficult, underlying,quality of life value questions.

We will consider both prognostic and predictive scenarios, with their distinct clinical value propositions and business model options. We focus on European markets as a case study and make the argument to extend the model to global markets.

Public Sector Adoption of Prognostic Testing for Early Stage Breast Cancer

Genomic Health pioneered the launch of this test category in the US with the OncotypeDXTM in 2004. More recently, several strong competitors have emerged, including Myriad Genetics’ EndoPredictTM, Agendia’sMammaprintTM, and NanoString’sProsignaTM tests. Unlike single-gene predictive testing, this category of tests does not benefit from the availability of alternative reimbursement models such as direct pharma sponsorship. From a market access perspective, these next-generation multi-marker tests may therefore provide a more accurate picture of the frontier of global public sector adoption of high complexity next generation tests.

Within Europe, breast prognostic tests now receive full national or intra-national (regional) public sector reimbursement in 12 countries9, as shown in the illustration.Outside Europe, public sector reimbursement is also available for a subset of these tests in Israel, Canada, Argentina, and Saudi Arabia.The Europeanlist includes: the UK, Germany, France (interim, via RIHN mechanism), Spain (regional only, in transition to national), Italy (regional only), the Netherlands, Switzerland, Denmark, Greece, Hungary, Ireland, and the Czech Republic. With the recent positive coverage decision of the German Federal Joint Committee (G-BA) for OncotypeDXin June, 201910, this list now includes the top 3 economies on the European continent. Note that the UK here is treated as a single country, but reimbursement practices and extent of national commissioning vary widely within each of the 4 constituent countries within the UK (England, Scotland, Wales andNorthern Ireland).

The journey towards reimbursement guidance for these tests in Europe has been a lengthy and challenging one; subsequent commissioning, deployment, and national rollout across these 12 countries remains a work in progress. For example, NICE (UK) guidance11 in December 2018 for the Genomic Health, Myriad, and Nanostring tests was, in fact, an update-replacement of earlier guidance issued in 201312 for OncotypeDXonly. In turn, the forerunner 2013 guidance had been in development since 2011. The 2018 NICE guidance, prompted by the intervening launch of newer tests, was based on a Multiple Technology Assessment of a total of 5 early breast prognostic tests, thus representing the most complex genomic assessment yet undertaken by NICE. Further, such NICE diagnostic guidance will become formally binding with effect from March, 2020 under the UK government Accelerated Access Collaborative initiative.

Consequently, the review period extended beyond NICE’s statutory timelines to a total of nearly 2 years and included detailed consideration of over 150 publications. The positive 2019 coverage decision by Germany’s Federal Joint Committee (G-BA) followed a previous unfavourable review back in 2016, in which G-BA and the German Institute for Quality and Efficiency in Health Care (IQWiG)took a different view on the weight of the evidentiary package which had resulted in the earlier (2013) UK NICE approval. In France, public health provision of such complex tests only began on a national scale in 2015 with the introduction of the RIHN innovation process13.

As previously noted, other public healthcare markets within Europe which have now adopted these multi-gene breast cancer prognostic tests include Spain and Italy, the Netherlands, Switzerland, Denmark, Greece, Hungary, Ireland, and the Czech Republic. For instance, Myriad Genetics has forged a path in some Italian and Spanish region for its EndoPredictTM test. Both markets are highly decentralized in terms of healthcare provision and commissioning, dictating such a regional strategy. In Spain, where OncotypeDXTM also has coverage approval, regional coverage can quickly lead to national coverage under the country’s equal access mandate.However, adoption on a national scale in Italy may be slower, due to the lack of coordinated central review by National Agency for Regional Healthcare Services (AGENAS) and the disparity in health technology assessment practices and wealth across its 20 regions.

Decisions in other European countries

A quick review reveals the following decisions and processes based on the progress recounted above:

  • France specifically introduced the interim coverage with evidence development RIHN mechanism for such novel technologies, and a successor program is anticipated to take effect within 2 years.
  • The decision in June2019 by Germany’s G-BA Committee represents the first of its kind in Germany, and one with significant internal political ramifications associated with the ongoing drive by the Federal Ministry of Health to reform the G-BA review process.
  • Sweden, Australia, and Canadareference NICE guidance, as do other countries made decisions that use similar cost effectiveness evaluation criteria.

The foregoing positive coverage decisions in Germany and other markets has resulted in significant upside going forward for Genomic Health and the other companies developing breast prognostic and other complex tests. For example, Genomic Health now generates 16% of its revenue outside the US. Whilesimilar to the equivalent proportion of sales from 5 years ago, it represents a 52% increase in revenue over this period from ex-US markets9. Another example: Myriad Genetics’ portfolio extends beyond its EndoPredictTM early breast prognostic test to include a prognostic test for prostate cancer (ProlarisTM) and other multi-marker diagnostic and monitoring tests.

Public Sector Adoption of Next Generation Sequencing (NGS) for Predictive Oncology

Prior to 2013, NGS and Sanger sequencing was generally provided only in the clinical research and trial context, via consortia of sequencing and pharmaceutical companies.Genomic sequencing has rapidly transitioned from the research stage to publicly funded clinical practice settings over these last 6 years. In parallel, individual corporate collaborations led to the first sequencing-based companion diagnostic tests. For example, Myriad Genetics’ sequencing-based BRACAnalysisTM became the first-ever laboratory developed test (LDT) approved by the FDA in 2014 as a companion test for Astra Zeneca’s LynparzaTM therapy14. This LDT was followed by the first FDA-approved companion label for Foundation Medicine’s FoundationONETM test in 201715.

Increasing numbers of such therapy-specific scenarios, together with the significant challenges associated with rare disease diagnosis, served to catalyse national level sponsorship of NGS. Starting in 2013, governments of at least 14 countries have invested over US $4B to date to establish national genomic-medicine initiatives with a focus on cancer and rare disease16(see Table 2). At the national level, as shown in the table, sponsors include the UK, the United States, France, Australia, Saudi Arabia, Turkey, Estonia, Denmark, Japan, Qatar, Switzerland, the Netherlands, Brazil, Finland and China. Programs vary by country, with the UK, US, Japan, France, Australia, Saudi Arabia, and Turkey having the most comprehensive access, while some are focused more on population-based sequencing programs (e.g. Denmark) or limited infrastructure development (e.g. Switzerland).

Countries investing in national genomic medicine initiatives since 2013
Country Type of program
UK Population-based sequencing, workforce and infrastructure development
France Population-based sequencing, workforce and infrastructure development
Australia Population-based sequencing, workforce and infrastructure development
Saudi Arabia Population-based sequencing, workforce and infrastructure development
Turkey Population-based sequencing, workforce and infrastructure development
USA Population-based sequencing projects
Estonia Population-based sequencing projects
Denmark Population-based sequencing projects
Japan Population-based sequencing projects
Qatar Population-based sequencing projects
Switzerland Infrastructure development
Netherlands Infrastructure development
Brazil Infrastructure development
Finland Infrastructure development

Table 2.  Countries investing in national genomic medicine initiatives since 201316

The last year has witnessed a tipping point in public sector access to NGS technology. This is illustrated by the US Centers for Medicare & Medicaid Services issuing a national coverage policy only in 201817, UK coverage via the new NHS Genomic Medicine Services being available only since October 201816and coverage being available in Japan only since 201818.

The actionability of broad NGS availability varies by country, however, since sequence variants often suggest off-label use of therapies. For example, while off-label prescribing is not prohibited in the US and China, it is restricted in Japan19, which limits the ability of patients in Japan to gain access to molecularly informed treatments. Nevertheless, the increasing public sector availability of comprehensive NGS-based tests represents a step change in the efficiency of matching cancer patients with suitable therapies.

Looking Forward

Over the past twenty years, precision medicine has migrated into clinics world-wide, country by country, with an ever-increasing pace of innovation as risks are retired and lessons-learned have informed ongoing uptake. Pre-2010, payor and public health system sponsorship of new precision medicine in many countries lagged significantly behind the science, and patient access was limited in most markets outside the US. Pharma-centric business models often prevailed and the diagnostic pathway, which focused on a single drug/target at a time, was inefficient as well as insufficient. Subsequently, more complex clinical tests such as OncotypeTM began to emerge; again, adoption was limited largely to the US, where generic coding schedules accommodated the associated laboratory procedures.

More recently (within the last ten years) test complexity, precision, and utility have evolved significantly; in parallel, innovation has been tracked by regulators and public sector health technology assessment bodies in many countries.As a consequence, complex offerings such as multi-gene breast cancer prognostic tests are now provided by the public sector in at least 17 nations, while public health systems in at least 14 nations are either offering or are preparing to offer NGS panels for oncology and rare disease diagnoses.These tests have in turn paved the way for other complex offerings extending the reach of precision medicine beyond oncology. Such tests include Non-Invasive Prenatal Testing (NIPT) panels and emerging AI-powered offerings.

Physicians world-wide now have access to precision medicine offerings that will significantly benefit their patients. In addition, the development climate has become more favourable for industrial sponsors. For pharma sponsors, there are real examples of the ability of precise targeting to reduce development attrition (e.g. Phase I to approval success probability increases from 8.4 to 25.9% with the inclusion of biomarkers20), reduce time to market (from 96 down to 32 months from first-in-man to approval for Tagrisso approval direct from Phase II21), and increase direct value accretion ($23B value loss for BMS attributed to non-optimal biomarker-based trial design22). For diagnostic developers, the value of precision is finally being recognized and quantified by diverse health technology assessment organizations, payors, and regulators. Hence, credible business and market access plans may now be made for a global, high-complexity diagnostic test portfolio, which will spur significant new investment in the sector.

Despite early slow progress, we can now look forward to 2020 and beyond to a global environment where development incentives are increasingly aligned with patient and healthcare system value.Consequently, patients worldwide will increasingly benefit from early access to precision medicine innovation.

References

Please add title of sites for each url in references, as I did for Refs 3 and 5.

  1. Miller, ID, Best Practices and Emerging Trends for Market Access to Personalised Medicine in the US and EU: Learnings for Global Developed and Emerging Markets. Current Pharmacogenomics and Personalized Medicine, 2014, 12, 104-113
  2. American Society of Clinical Oncology, Leukemia – Chronic Myeloid – CML: Statistics, 2015 – Insert where one find this source, please.
  3. Personalized Medicine 2018: More Drugs, Greater NGS Adoption, Growing Appreciation of Dx Value,https://www.360dx.com/molecular-diagnostics/personalized-medicine-2018-more-drugs-greater-ngs-adoption-growing#.XYtI-i2ZPOQNOTE – this is a premium access report – not all our readers may have the subscription
  4. Epemed 2011 article Insert where one find this source, please.
  5. CPT® Proprietary Laboratory Analyses Codes, https://www.ama-assn.org/practice-management/cpt/cpt-pla-codes, Source: American Medical Association
  6. Miller, ID, The evolution of high complexity companion testing for targeted and immuno-oncology. Personalized Medicine. Personalized Medicine, 13, No. 5Commentary
  7. https://www.fda.gov/news-events/press-announcements/fda-approves-first-cancer-treatment-any-solid-tumor-specific-genetic-feature
  8. https://www.fda.gov/news-events/press-announcements/fda-approves-oncology-drug-targets-key-genetic-driver-cancer-rather-specific-type-tumor
  9. Author analysis of financial reports and presentations from Genomic Health, Nanostring and Myriad Genetics
  10. https://www.g-ba.de/presse/pressemitteilungen/800/ (original source, in German)
  11. https://www.nice.org.uk/guidance/dg34
  12. https://www.nice.org.uk/guidance/dg10
  13. https://www.medtecheurope.org/wp-content/uploads/2018/06/2018_MTE_MTRC-Research-Paper-Innovative-Payment-Schemes-in-Europe.PDF
  14. https://myriad.com/about-myriad/inside-myriad/company-milestones/
  15. http://investors.foundationmedicine.com/news-releases/news-release-details/fda-approves-foundation-medicines-foundationone-cdxtm-first-and
  16. Stark, Z, Dolman, L, Manolio, TA et al. Integrating Genomics into Healthcare: A Global Responsibility. The American Journal of Human Genetics 104, 13–20, January 3, 2019
  17. https://www.cms.gov/newsroom/press-releases/cms-finalizes-coverage-next-generation-sequencing-tests-ensuring-enhanced-access-cancer-patients
  18. https://www.genomeweb.com/molecular-diagnostics/foundation-medicine-cancer-cdx-approved-japan#.XYt1uy2ZPOQ
  19. https://www.precisiononcologynews.com/cancer/japan-china-launch-basket-umbrella-trials-expand-precision-oncology-treatment-access.
  20. https://www.bio.org/press-release/bio-releases-largest-study-ever-clinical-development-success-rates
  21. https://www.drugs.com/history/tagrisso.html

https://www.ft.com/content/11d3b770-5b14-11e6-9f70-badea1b336d4