The Future of Personalized Medicine in Space: From Observations to Countermeasures.

The aim of personalized medicine is to detach from a "one-size fits all approach" and improve patient health by individualization to achieve the best outcomes in disease prevention, diagnosis and treatment. Technological advances in sequencing, improved knowledge of omics, integration with bioinformatics and new in vitro testing formats, have enabled personalized medicine to become a reality. Individual variation in response to environmental factors can affect susceptibility to disease and response to treatments. Space travel exposes humans to environmental stressors that lead to physiological adaptations, from altered cell behavior to abnormal tissue responses, including immune system impairment. In the context of human space flight research, human health studies have shown a significant inter-individual variability in response to space analogue conditions. A substantial degree of variability has been noticed in response to medications (from both an efficacy and toxicity perspective) as well as in susceptibility to damage from radiation exposure and in physiological changes such as loss of bone mineral density and muscle mass in response to deconditioning. At present, personalized medicine for astronauts is limited. With the advent of longer duration missions beyond low Earth orbit, it is imperative that space agencies adopt a personalized strategy for each astronaut, starting from pre-emptive personalized pre-clinical approaches through to individualized countermeasures to minimize harmful physiological changes and find targeted treatment for disease. Advances in space medicine can also be translated to terrestrial applications, and vice versa. This review places the astronaut at the center of personalized medicine, will appraise existing evidence and future preclinical tools as well as clinical, ethical and legal considerations for future space travel.

Optimizing Patient Selection to Maximize Drug Efficacy: the Expanding Role of Pharmacogenomics in the Clinical Development of Pembrolizumab for the Treatment of Non-small Cell Lung Cancer.

Pembrolizumab (MK-3475) is a potent and highly selective humanized monoclonal antibody of the immunoglobulin G4κ class directed against the immune checkpoint programmed cell death protein-1 (PD-1). Binding to PD-1 prevents its interaction with natural ligands and allows for the reactivation of the immune response against cancer cells. The list of approved indications of pembrolizumab is fast expanding, including its use as first-line treatment of metastatic non-small cell lung cancer (NSCLC), which is a complex and evolving disease. Pharmacogenomics significantly contributed to understanding this complexity, allowing for the identification of molecular biomarkers and novel pharmacologic targets. This approach has delivered more effective and less toxic drugs for advanced NSCLC. In our opinion, pharmacogenomics played a key role in the approval of pembrolizumab as frontline therapy for NSCLC with high expression of the PD-1 ligand, which occurs in ∼30% of patients. Moreover, an analysis conducted on the ongoing clinical trials sponsored by the drug's patent holder shows that the characterization and validation of additional pharmacogenomic biomarkers of response has the potential to extend the frontline clinical use of pembrolizumab in NSCLC.

Detection of HLA-B*57:01 by real-time PCR: implementation into routine clinical practice and additional validation data.

AIM: HLA-B*57:01 status needs to be determined before initiating abacavir therapy. We developed a pharmacogenetic real-time (Q)-PCR screening test using two sets of sequence specific primers. This test has been implemented into routine clinical practice. MATERIALS & METHODS: HIV-infected patients admitted at our University Hospital were thus genotyped using the above mentioned test. A panel of 80 DNA samples with a known genotype were used to characterize Q-PCR conditions using different master mixes. RESULTS: A total of 353 patients were genotyped, detecting 15 (4.25%) HLA-B*57:01 positive carriers. Among the negative patients, 17.2% were treated with abacavir without any hypersensitivity reaction. Using different Q-PCR master mixes, significantly lower cutoff Ct values were found, thus new analytical settings are provided. CONCLUSION: The pharmacogenetic test developed in our laboratory for the fast screening of HLA-B*57:01 can be successfully implemented into routine clinical practice. All 16 sequences (including an additional six) currently known for the HLA-B*57:01 allele are detected by sequence specific primers used in this test. The Brilliant II SYBR(®) Green QPCR MM (Stratagene) can safely replace the master mix originally used to develop the test.