Pharmacogenomics in early-phase clinical development.

Pharmacogenomics (PGx) offers the promise of utilizing genetic fingerprints to predict individual responses to drugs in terms of safety, efficacy and pharmacokinetics. Early-phase clinical trial PGx applications can identify human genome variations that are meaningful to study design, selection of participants, allocation of resources and clinical research ethics. Results can inform later-phase study design and pipeline developmental decisions. Nevertheless, our review of the clinicaltrials.gov database demonstrates that PGx is rarely used by drug developers. Of the total 323 trials that included PGx as an outcome, 80% have been conducted by academic institutions after initial regulatory approval. Barriers for the application of PGx are discussed. We propose a framework for the role of PGx in early-phase drug development and recommend PGx be universally considered in study design, result interpretation and hypothesis generation for later-phase studies, but PGx results from underpowered studies should not be used by themselves to terminate drug-development programs

Pharmacogenomic technologies: a necessary "luxury" for better global public health?

<p>Abstract</p> <p>Background</p> <p>Pharmacogenomic technologies aim to redirect drug development to increase safety and efficacy of individual care. There is much hope that their implementation in the drug development process will help respond to population health needs, particularly in developing countries. However, there is also fear that novel pharmacogenomic drugs will remain too costly, be designed for the needs of the wealthy nations, and so constitute an unnecessary "luxury" for most populations. In this paper, we analyse the promise that pharmacogenomic technologies hold for improving global public health and identify strategies and challenges associated with their implementation.</p> <p>Discussion</p> <p>This paper evaluates the capacity of pharmacogenomic technologies to meet six criteria described by the University of Toronto Joint Centre for Bioethics group: 1) impact of the technology, 2) technology appropriateness, 3) capacity to address local burdens, 4) feasibility to be implemented in reasonable time, 5) capacity to reduce the knowledge gap, and 6) capacity for indirect benefits. We argue that the implementation of pharmacogenomic technologies in the drug development process can positively impact population health. However, this positive impact depends on <it>how </it>and for <it>which purposes </it>the technologies are used. We discuss the potential of these technologies to stimulate drug discovery in the case of rare (orphan diseases) or neglected diseases, but also to reduce acute adverse drug reactions in infectious disease treatment and prevention, which promises to improve global public health.</p> <p>Conclusions</p> <p>The implementation of pharmacogenomic technologies may lead to the development of drugs that appear to be a "luxury" for populations in need of numerous interventions that are known to have a demonstrable impact on population health (e.g., secure access to potable water, reduction of social inequities, health education). However, our analysis shows that pharmacogenomic technologies do have the potential to redirect drug development and distribution so as to improve the health of vulnerable populations. Strategies should thus be developed to better direct their implementation towards meeting the needs and responding to the realities of populations of the developing world (i.e., social, cultural and political acceptability, and local health burdens), making pharmacogenomic technologies a necessary "luxury" for global public health.</p

Contexte mondial de développement de la recherche en pharmacogénomique et justice en santé mondiale

Le contexte actuel de la distribution des soins de santé se caractérise par la présence d’inégalités frappantes en termes d’accès aux médicaments ou autres technologies thérapeutiques (appareils ou tests de diagnostic) à l’échelle mondiale. Cette distribution dépend de plusieurs facteurs politiques, sociaux, économiques, scientifiques et éthiques. Parmi les facteurs importants, l’innovation dans les milieux biomédical et pharmaceutique participe activement à l’établissement et à l’exacerbation des inégalités en santé mondiale. Dans cette thèse, nous présentons une étude basée sur le cas des technologies issues de la pharmacogénomique. Il est proposé que ces technologies soient susceptibles d’avoir un impact positif sur la santé publique à l’échelle mondiale en révolutionnant le modèle de développement et de distribution du médicament. Nous avons réalisé une évaluation du potentiel qu’offre l’application de ces technologies dans les domaines de la recherche biomédicale et pharmaceutique pour les populations des pays à faible et à moyen revenu. Nous démontrons que les efforts en recherche dans le domaine de la pharmacogénomique sont essentiellement dirigés vers les maladies affectant les populations des pays à revenu élevé. Par cela, le développement de la recherche dans ce domaine réplique le modèle du ratio 90/10 des inégalités en santé mondiale, où 90 % des médicaments produits accommode seulement 10 % de la population mondiale – soit celle des pays à revenu élevé. Il appert que le potentiel d’utilisation des technologies issues de la pharmacogénomique pour les populations des pays à faible et à moyen revenu nécessite alors une redéfinition des rôles et des responsabilités des acteurs en santé mondiale (les gouvernements, les organisations gouvernementales et non gouvernementales internationales et les compagnies pharmaceutiques). Nous proposons que cette redéfinition des rôles et des responsabilités des différents acteurs passe par l’adoption d’un cadre réflexif basé sur les principes éthiques de la justice, de l’équité et de la solidarité dans le développement de la recherche et l’implantation des nouvelles technologies -omiques.Stricking inequalities characterize the current global context in drug development and distribution, raising serious concerns of justice in global health. These global health issues result from political, social, economic, scientific and ethical factors, amongst which the development of new technologies can contribute to increased inequalities across and within populations. Pharmacogenomics knowledge and technologies, which couple genomics information with pharmaceutical drug response, have been promised to revolutionize both drug development and prescription worldwide. In this way, pharmacogenomic technologies promise to increase justice in global health, by incentivizing public research laboratories and pharmaceutical companies to develop drugs for populations (e.g., in low and middle-income countries) that have been neglected by the traditional drug development model. In this thesis, we conducted an evaluation of the potential that pharmacogenomic technologies hold towards increased health for populations of low and middle-income countries (LMIC). Our results demonstrate that, although these technologies hold promising potential for the health of LMIC populations, pharmacogenomics research has focused mostly on diseases prevalent in High-income countries. Pharmacogenomics research over the last decade has thus replicated the well-known 90/10 ratio in drug development and, as such, fails to contribute to reducing global health inequalities. We suggest that, in order to fulfill the promise of increased health for populations of LMIC, the roles and responsibilities of the various actors involved in global health (e.g. local governements, international organizations, and pharmaceutical companies) must be redesigned. We argue that rethinking these roles and responsibilities requires a decision Framework based on considerations of justice, equity and solidarity