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Supplements Exploring the Evolving Landscape of Precision Medicine

Regulations That Ensure the Quality of Precision Medicine

Xi Xu, 2018 PharmD Candidate, and Michael R. Page, PharmD, RPh
Introduction to Personalized Medicine
Personalized medicine is a broad term that encompasses a movement toward use of specific biomarkers and tests to tailor therapy for each patient to optimize outcomes. For health systems, personalized medicine has the potential to improve the efficiency of diagnosis and enable prescribing of the right medications for each patient. In its current form, personalized medicine is largely limited to the use of specific genetic biomarkers to select treatments for subgroups of patients.1 As the cost of genetic testing decreases exponentially, falling from $40 million per human genome sequenced in October 2003 to $1200 in October 2015, technological costs associated with implementing precision medicine continue to fall (Figure 1).2

Personalized medicine has many advantages over traditional methods of treatment (Table 11,3). Although traditional nontargeted medications may use a one-size-fits-all approach to treatment, personalized medicine allows for the use of targeted treatments for certain patients with specific genetic mutations. It has been estimated that only one-fourth of patients treated with classic cancer treatment regimens respond to therapy, with similarly low rates of treatment success in other domains of medicine (Figure 24). Through personalized medicine, it may be possible to improve rates of response in many conditions by treating patients for the specific molecular pathologies underlying their disease.
 
Examples of Patients Benefitting From Personalized Medicine
Diagnostic tests are a major component of personalized medicine. They are used to predict patient response to therapies, prevent medication-related adverse events, and assist physicians in determining the appropriate medication and treatment dose to match each patient’s specific disease features. For instance, in breast cancer, patients with the HER2 (ERBB2) mutation may receive the targeted agent trastuzumab.5 Similarly, in patients with lung cancer, testing for levels of PD-L1 helps determine if the patient is a candidate for treatment with immunotherapies.6,7
Targeted therapy is not limited to treatment of patients with cancer. A genetic screening tool has been developed to help prevent a life-threatening hypersensitivity reaction in patients with HIV receiving treatment with abacavir.8,9 Also, patients receiving abacavir are tested for the HLA-B*5701 allele, which is associated with abacavir-related hypersensitivity reactions.9

Other treatments may promote better use of existing treatments, including warfarin, which is known for its highly individualized dosing and narrow therapeutic index. Many factors play a role in determining the right dose of warfarin. In addition to patient’s weight, age, gender, race, height, lifestyles and current medications, several genes also influence the concentration of warfarin in the body and thereby dosing. The CYP2C9 gene encodes for an enzyme that is important in the metabolism of warfarin.10 Analyzing expression of CYP2C9 and other genetic variants may be helpful in determining the appropriate dose and optimizing therapy.11,12
 
Liquid Biopsy
Liquid biopsy involves noninvasive testing of body fluids to detect tumor DNA and analyze tumor genetic material to optimize patient treatment and management. Samples may be obtained from saliva, cerebrospinal fluid, blood, urine, and seminal fluids.3 As part of personalized medicine, liquid biopsy is less invasive than traditional biopsy methods and may reveal more of the genetic heterogeneity of the genetic features of cancer.3 Examples of liquid biopsy technologies include Progensa, CellSearch, and AlloMap.

Although liquid biopsy cannot yet replace tissue biopsy, its results can provide information to supplement tumor biopsy. One example is the Progensa prostate cancer antigen 3 (PCA3) urine test, which is FDA-approved for use in men 50 years and older with 1 or more previously negative prostate biopsies. Both PCA3 and prostate-specific antigen (PSA) concentrations are measured from the urine and the ratio of PCA3 to PSA is calculated. The ratio can help physicians determine the chance of a positive prostate biopsy.13

The CellSearch circulating tumor cell (CTC) test is a blood test, approved by FDA in 2007, that monitors disease progression in patients with metastatic prostate cancer. A high level of CTCs in the blood indicates a worsened prognosis and poor treatment response. At baseline, patients with low CTC counts have higher survival rates than patients with high CTC counts.14 Physicians can order non-invasive CTC counts anytime during treatment to monitor cancer progression and tailor therapies accordingly.3

AlloMap is an FDA-approved blood test widely used to predict the risk of rejection in heart transplant patients 15 years and older while saving them from invasive tissue biopsies.15 International Society for Heart & Lung Transplantation guidelines recommend the use of AlloMap as a noninvasive means of monitoring patients for potential heart transplant rejection.16

FDA’s Regulation of In Vitro Diagnostics, Laboratory Developed Tests, and Companion Diagnostics in Relationship to Personalized Medicine
A companion diagnostic medical device is defined as an in vitro diagnostic (IVD) used to determine the safety and effective use of a therapeutic product. Companion diagnostics can identify the groups of patients highly likely to respond to a medication, predict side effects, and monitor response to a medication.17,18 The FDA also categorizes laboratory-developed tests (LDTs) as a type of IVD that detect analytes such as DNA.19

Traditionally, the Centers for Medicare & Medicaid Services (CMS) has had jurisdiction over LDTs through the Clinical Laboratory Improvement Amendments (CLIA) Act, while the FDA regulates IVDs as medical devices. Although LDTs are considered IVDs and supposedly regulated by the FDA, the agency has exercised enforcement discretion in the past and exempted some LDTs from the extensive processes needed to attain premarket approval.19,20 For instance, the Trofile co-receptor tropism assay by Monogram Biosciences was used in the clinical trials program for maraviroc before the drug’s approval in 2007. Because this assay was important in selecting patients for treatment with maraviroc, as the antiretroviral drug is only indicated for patients with CCR5-tropic HIV-1, the FDA decided to forgo premarket review of the assay prior to sale.20,21

An example of the FDA subjecting an LDT to premarket approval occurred in 2005 when a warning letter was issued to Agendia BV for its MammaPrint breast cancer recurrence assay. FDA officials were concerned about a lack of data showing clinical benefits to the patients. The FDA only gave its approval in 2008 for marketing of MammaPrint after the makers proved the test clinically beneficial to patients with breast cancer.22 As part of the process, the FDA also reclassified MammaPrint as an IVDMIA (in vitro diagnostic multivariate index assay), a type of LDT.20

A lack of consistency in the regulation of LDTs, however, may hinder manufacturers from producing high-quality screening tests that meet the standard of care for safe and effective medication use in patients. For example, the FDA issued a safety alert in September 2016 regarding ovarian cancer screening tests. In the alert, officials stated that there are no screening tests currently accurate enough to detect ovarian cancer, contrary to many companies’ advertisements. They warned that unreliable tests may lead to false-positive or false-negative results. A false-positive result may lead women to use other medical tests and undergo needless surgeries, increasing healthcare costs, whereas a false-negative result may delay necessary treatment in asymptomatic women at higher risk of developing ovarian cancer.23

After posting a draft on the LDT regulations in 2014, the FDA organized the comments received and posted a revised discussion paper on LDT regulations in 2017. The revised document is a working guidance, as the FDA invites further comments and suggestions.19 However, considerable feedback has already been incorporated. In development of the current draft, the FDA interpreted over 300 sets of comments, summarizing them into several common themes regarding adoption of LDT guidelines, including19:
  • Risk-based classification, oversight, and review of LDTs
  • Premarket review for selected LDTs
  • Analytically driven and clinical validity-driven assessment of LDTs for approval
  • Grandfathering of LDTs already on the market
  • LDT performance and validity of the test for approval
 
In the paper, the FDA proposed exempting certain LDTs from premarket reviews while subjecting other LDTs to premarket reviews (Table 219). According to the agency, the current risk-based protocols for the premarket reviews of LDTs may not be adopted into common practice for at least 4 years (Table 319).19 Through this process, the FDA and CMS will divide responsibilities to ensure that quality standards are followed for all new and existing personalized medicine diagnostic assays.19
 
Conclusion
As the potential and value of personalized medicine continues to be realized, regulation of this expanding field continues to be a challenge. However, these challenges are positive in that they are a sign of a burgeoning field with great potential for growth and advancement. As the scope of personalized medicine widens, regulations for diagnostic tests will continue to be important. Ensuring the tests’ quality and appropriate is a critical area for FDA oversight.
1. Personalized Medicine Coalition. The Personalized Medicine Report: Opportunity, Challenges, and the Future. Washington, DC: Personalized Medicine Coalition; 2017.
2. National Human Genome Research Institute. DNA sequencing costs: data. NHGRI website. www.genome.gov/sequencingcostsdata/. Updated May 24, 2016. Accessed June 9, 2017.
3. Di Meo A, Bartlett J, Cheng Y, Pasic MD, Yousef GM. Liquid biopsy: a step forward towards precision medicine in urologic malignancies. Mol Cancer. 2017;16(1):80. doi: 10.1186/s12943-017-0644-5.
4. Spear BB, Heath-Chiozzi M, Huff J. Clinical application of pharmacogenetics. Trends Mol Med. 2001;7(5):201-204.
5. Trastuzumab [package insert]. South San Francisco, CA: Genentech, Inc; 2017.
6. FDA. Dako. PD-L1 IHC 22C3 pharmDx. https://www.accessdata.fda.gov/cdrh_docs/pdf15/P150013c.pdf. Accessed July 2017.
7. FDA approves Keytruda for advanced non–small cell lung cancer [news release]. Silver Spring, MD: FDA; October 2, 2015. www.fda.gov/NewsEvents/Newsroom/PressAnnouncements/ucm465444.htm. Accessed June 14, 2017.
8. Guidelines for the use of antiretroviral agents in HIV-1-infected adults and adolescents. HHS AIDS Info website. aidsinfo.nih.gov/contentfiles/lvguidelines/adultandadolescentgl.pdf. Updated July 14, 2016. Accessed June 13, 2017.
9. Abacavir [package insert]. Research Triangle Park, NC: GlaxoSmithKline; 2017.
10. Novelli G. Personalized genomic medicine. Intern Emerg Med. 2010;5(suppl 1):S81-S90. doi:10.1007/s11739-010-0455-9.
11. Warfarin [package insert]. Princeton, NJ: Bristol-Myers Squibb; 2017
12. Lexicomp Online. Warfarin Lexi-Drugs monograph, Hudson, Ohio: Lexi-Comp, Inc. Accessed June 15, 2017.
13. FDA. Progensa: summary of safety and effectiveness data. https://www.accessdata.fda.gov/cdrh_docs/pdf10/P100033b.pdf. Updated February 13, 2012. Accessed July 2017.
14. FDA clears CellSearch circulating tumor cell test [news release]. Raritan, NJ: Johnson & Johnson; February 27, 2008. www.investor.jnj.com/releasedetail.cfm?releaseid=296494. Accessed June 14, 2017.
15. 510(k) substantial equivalence determination decision summary: assay and instrument combination template. FDA website. www.accessdata.fda.gov/cdrh_docs/reviews/K073482.pdf. Accessed July 21, 2017.
16. Costanzo MR, Dipchand A, Starling R, et al; International Society of Heart and Lung Transplantation Guidelines. The International Society of Heart and Lung Transplantation Guidelines for the care of heart transplant recipients. J Heart Lung Transplant. 2010;29(8)914-956. doi: 10.1016/j.healun.2010.05.034
17. Companion diagnostics. FDA website. www.fda.gov/MedicalDevices/ProductsandMedicalProcedures/InVitroDiagnostics/ucm407297.htm. Updated October 5, 2016. Accessed June 14, 2017.
18. Overview of IVD regulation. FDA website. www.fda.gov/MedicalDevices/DeviceRegulationandGuidance/IVDRegulatoryAssistance/ucm123682.htm. Updated March 19, 2015. Accessed June 15, 2017
19. Laboratory developed tests. FDA website. www.fda.gov/medicaldevices/productsandmedicalprocedures/invitrodiagnostics/laboratorydevelopedtests/default.htm. Updated January 13, 2017. Accessed June 15, 2017
20. Personalized Medicine Coalition. Pathways for Oversight of Diagnostics. Washington, DC: Personalized Medicine Coalition; 2013.
21. Selzentry [package insert]. New York, NY: Pfizer Inc; 2007.
22. 510(k) substantial equivalence determination decision summary. FDA website. www.accessdata.fda.gov/cdrh_docs/reviews/K062694.pdf. Published 2008. Accessed June 15, 2017.
23. Ovarian cancer screening tests: safety communication ­ FDA recommends against use. FDA website. www.fda.gov/Safety/MedWatch/SafetyInformation/SafetyAlertsforHumanMedicalProducts/ucm519540.htm. Published September 7, 2016. Updated September 7, 2016. Accessed June 12,2017.
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