A: Genome sequencing for cancer and undiagnosed diseases is beginning to become part of clinical care, and wearable devices such as smartwatches that can be used to measure physiology and health are becoming commonplace as direct to consumer devices. Gene therapies using antisense oligonucleotides are just emerging to treat specific diseases and clinical trials involving CRISPR are underway for treating HIV and blood diseases. So we are on the cusp of seeing a wide variety of new technologies being used for clinical purposes with many more innovative technologies to come within the next years.

A: Prevention is better than cure. For many diseases, key to that idea is our capacity to detect and decode molecular alterations that precede the onset of symptoms and evaluate disease risks on a personalized level. Among the most promising technologies to probe an individual’s molecular landscape of health are ultra-sensitive mass spectrometers in conjunction with advanced computational strategies with which we can explore functional molecular layers such as proteins and metabolites. With this ‘multi-omics’ effort we already characterize disease mechanisms and identify new biomarkers for early diagnosis.

A: In short, we have to invest in research and development. Technologies such as large-scale mass spectrometric molecular profiling to assess the health state will have to become more streamlined, robust, cheap and simple for routine clinical applications. In addition, interpretation of increasingly complex molecular data will greatly benefit from combining tailored computational strategies with in-depth biological and biochemical expertise.

A: Transforming research platforms to safe and reliable clinical pipelines is challenging because clinical applications require the highest standards for safety and data integrity. For instance, integration of clinical mass spectrometry to measure physiology and health will benefit from improved accuracy and precision of data acquisition and necessitates standardization across institutes. This is a multidisciplinary effort, and we have to identify optimal strategies to encourage collaborations between the clinic, industry and academia, from medical doctors to engineers. Moreover, we will have to engage in an open and educated discussion about socioeconomic, political, as well as very personal implications of the ability to probe an individual’s molecular landscape of health.

A: Under the umbrella of Stanford, our cross-disciplinary team develops multi-omics precision medicine strategies –integrating metabolites, proteins and DNA/RNA with clinical parameters– to transform medicine from reactive to preventive. My personal mission is to develop and apply mass spectrometry and computational strategies to understand the biological role of lipids in health and disease. Lipids are a largely unexplored molecular class and I am integrating lipids in our multi-omics efforts to enhance our systems biology understanding of human physiology.

A: To tackle complex scientific questions ahead of us we rely on collaborative, interdisciplinary teams that celebrate failing, in order to learn, improve and progress. In part, academia is not optimally calibrated to support that strategy. Career trajectories that depend on publishing positive results in certain journals with specific authorship positions in a timely manner are adverse to the scientific principles of collaboration and transparency. In the best interest of science and progress, we should critically review some of our policies.