Genomic sequencing has been compared to piecing together a giant biological jigsaw puzzle. It is an arduous, slow process, somewhat prone to error and fraught with technical, practical and ethical complications that make its widespread implementation very challenging for the time being, even in the most advanced healthcare systems. Yet genomic sequencing is simple compared with the broader healthcare aim to which it contributes: personalised medicine, the ability to precisely tailor therapies to the genetic profile of patients and their diseases, thereby increasing efficacy, improving patient outcomes and quality of life and ultimately reducing treatment costs.
This distant endpoint holds so much promise that it is tempting to call for large public and public–private investments, akin to the $215 million that President Obama requested of the US Congress in his 2016 budget.1 The unwritten rules of globalised one-upmanship would also have Europe match or even surpass the investments of its competitors in scientific innovation to consecrate its place in the vanguard of biomedical and -omics research. However, before the vision of personalised medicine can be fully realised, a host of complex obstacles must be overcome – painstakingly, deliberately and incrementally. European health systems would perhaps be best served by an in-depth situation analysis and a long-term strategy that sets out system goals rooted in equity, patience and proportionality.
Many health system stakeholders, including the European Society of Medical Oncology (ESMO), have speculated on the future of personalised cancer care.2–4 The particular relevance of these therapies to oncology is undeniable (as we have seen with new targeted therapies for metastatic breast cancer,5 myeloid leukaemia,6 melanoma7) and others, but the oncology community should not underestimate the challenges facing the field, least of all the immense costs and technical demands in collecting, storing and processing the amount of data needed for functional biobanks. The need for researchers to access these data on a large scale raises problems related to equity and distribution of cost burden, as well as privacy and intellectual property. To overcome the technological hurdles, we may need to wait for the development of a whole new field of study – healthcare knowledge engineering – that today is in its infancy.8 The regulatory landscape must also be transformed: although market approval for pharmaceuticals is centralised through the European Medicines Agency (EMA), the companion diagnostics are only partially and heterogeneously regulated at a national level, undermining the consistency, comparability and quality of precision diagnostics. Health technology assessments will also undergo a shift in paradigm, for large up-front investments must be weighed against benefits that will be seen only in the long term. In professional training, the sheer speed of progress in the -omics field makes medical curricula obsolete almost as quickly as they are developed; specific to oncology, we know that the genetic profiles of tumours vary widely and evolve over time, creating a possible need for multiple, invasive biopsies among cancer patients, with no assurance or even hope of immediate clinical benefits.
These considerable challenges will be overcome only with time, and progress will be largely incremental, dependent on the gradual maturation of the discipline, emerging technological and computational advances and a sustainable stream of wisely directed research investments. In consideration of the potential epidemiological value of consolidated international biobanks, European countries would be wise to work together. But in light of the high initial costs, it is unrealistic – even perverse – to expect the low- and middle-income countries in the east and the south to use scarce resources for this purpose. One widely held conviction, which crystallised in the ESMO Emerging Countries Committee during the 2014 ESMO Conference in Madrid, was that resource-strapped countries in Europe, Africa and the Americas could ill afford to pursue precision therapies and should instead concentrate on securing access to essential medicines, basic diagnostic equipment and training.9–10 The next stage of personalised medicine should rather be investigated in flagship cancer centres in high-income countries.11 Thus, in the context of the real and formidable health inequities persisting throughout Europe and the world, personalised medicine could instead be one more driver of health inequity on a continent that is already plagued by wide gaps in access to quality care.
The ultimate difference, in this as in so many other cases, will be in the leadership shown by national and international bodies, including ministries of health and the European Commission. Specifically, we require a joint strategy on personalised medicine in Europe, developed through a transparent and participatory approach. This roadmap should set out the basic principles and objectives for the -omics fields, including considerations for patient participation and equity. Research investments should be scoped towards the long term, but resource allocation should be proportional to the benefits perceived in the near term and be supported by the same type of economic evaluations to which medicines, surgery and radiotherapy techniques are currently submitted.12 Indeed, even the best-supplied health systems in Europe are struggling to finance and provide timely services for citizens; it would be unconscionable to use tax contributions to raise the ceiling on innovation with no certainty about benefits and costs. Only through a common European vision, buttressed by the principles of solidarity, collaboration and good governance, will personalised medicine truly achieve gains for the entire European population.
