Biomarkers for Precision Patient Selection in Cancer Therapy Approvals in the US, from 2011 to 2023.

During the period of 2011-2023, the US Food and Drug Administration (US FDA) granted 139 accelerated and 329 regular approvals for 86 and 152 cancer therapeutic products, respectively. The percentage of approvals for a biomarker-defined population was numerically higher in accelerated approvals in comparison to regular approvals, that is, 48% vs. 40%. From 2011-2016 to 2017-2023, there was an increasing number of approvals with biomarker-defined populations in lung and breast cancers, serving as the primary driver for the overall increase in the percentage of approvals for biomarker-defined populations in solid tumors relative to hematological malignancies. Over the years, approvals were incorporating a more diverse collection of distinct biomarkers, from 3 in 2011 to 16 in 2022. Overall, HER2, hormone receptor (HR), EGFR, ALK, BRAF, and PD-L1-defined populations received the highest numbers of approvals. The FDA decision on approving a biomarker-defined or an all-comers population may depend on a number of factors and may evolve over time based on emerging evidence. The review discusses selected FDA approvals where a pivotal trial enrolled an all-comers population but the approved indication was restricted to a biomarker-defined population, as well as challenges in clinical trial design in the context of precision medicine. The prominent role of biomarkers in optimizing trial design and identifying a population most likely to benefit from treatment underlines the significance of a comprehensive understanding of disease biology and drug mechanisms. Our review illustrates that biomarker-driven approaches enhance the likelihood of identifying optimal patient populations, potentially streamlining trials through accelerated approval pathways for cancer drug development.

Updates in SJS/TEN: collaboration, innovation, and community.

Stevens-Johnson Syndrome/Toxic Epidermal Necrolysis (SJS/TEN) is a predominantly drug-induced disease, with a mortality rate of 15-20%, that engages the expertise of multiple disciplines: dermatology, allergy, immunology, clinical pharmacology, burn surgery, ophthalmology, urogynecology, and psychiatry. SJS/TEN has an incidence of 1-5/million persons per year in the United States, with even higher rates globally. One of the challenges of SJS/TEN has been developing the research infrastructure and coordination to answer questions capable of transforming clinical care and leading to improved patient outcomes. SJS/TEN 2021, the third research meeting of its kind, was held as a virtual meeting on August 28-29, 2021. The meeting brought together 428 international scientists, in addition to a community of 140 SJS/TEN survivors and family members. The goal of the meeting was to brainstorm strategies to support the continued growth of an international SJS/TEN research network, bridging science and the community. The community workshop section of the meeting focused on eight primary themes: mental health, eye care, SJS/TEN in children, non-drug induced SJS/TEN, long-term health complications, new advances in mechanisms and basic science, managing long-term scarring, considerations for skin of color, and COVID-19 vaccines. The meeting featured several important updates and identified areas of unmet research and clinical need that will be highlighted in this white paper.

Pharmacogenetic Labeling of FDA-Approved Drugs: A Regulatory Retrospective.

The U.S. Food and Drug Administration recently marked 10 years since first updating the labeling for warfarin (often referred to as the "poster child" of pharmacogenomics) to include information regarding the potential impact of CYP2C9 and VKORC1 genetic variation on warfarin dosing requirements and risks. Herein, we opine on the experience updating the warfarin labeling, highlighting more generally the enabling factors and challenges encountered when considering incorporation of pharmacogenomic information into the prescribing recommendations for already approved drugs. We also provide a historical perspective of implemented changes in regulatory policies related to personalized medicine.

Pharmacogenetics in the evaluation of new drugs: a multiregional regulatory perspective.

Pharmacogenetics, one of the cornerstones of personalized medicine, has the potential to change the way in which health care is offered by stratifying patients into various pretreatment categories, such as likely responders, likely non-responders or likely to experience adverse drug reactions. In order to advance drug development and regulatory science, regulatory agencies globally have promulgated guidelines on pharmacogenetics for nearly a decade. The aim of this article is to provide an overview of new guidelines for the implementation of pharmacogenetics in drug development from a multiregional regulatory perspective - encompassing Europe, the United States and Japan - with an emphasis on clinical pharmacokinetics.

Alpha-1 antitrypsin protein and gene therapies decrease autoimmunity and delay arthritis development in mouse model.

BACKGROUND: Alpha-1 antitrypsin (AAT) is a multi-functional protein that has anti-inflammatory and tissue protective properties. We previously reported that human AAT (hAAT) gene therapy prevented autoimmune diabetes in non-obese diabetic (NOD) mice and suppressed arthritis development in combination with doxycycline in mice. In the present study we investigated the feasibility of hAAT monotherapy for the treatment of chronic arthritis in collagen-induced arthritis (CIA), a mouse model of rheumatoid arthritis (RA). METHODS: DBA/1 mice were immunized with bovine type II collagen (bCII) to induce arthritis. These mice were pretreated either with hAAT protein or with recombinant adeno-associated virus vector expressing hAAT (rAAV-hAAT). Control groups received saline injections. Arthritis development was evaluated by prevalence of arthritis and arthritic index. Serum levels of B-cell activating factor of the TNF-α family (BAFF), antibodies against both bovine (bCII) and mouse collagen II (mCII) were tested by ELISA. RESULTS: Human AAT protein therapy as well as recombinant adeno-associated virus (rAAV8)-mediated hAAT gene therapy significantly delayed onset and ameliorated disease development of arthritis in CIA mouse model. Importantly, hAAT therapies significantly reduced serum levels of BAFF and autoantibodies against bCII and mCII, suggesting that the effects are mediated via B-cells, at least partially. CONCLUSION: These results present a new drug for arthritis therapy. Human AAT protein and gene therapies are able to ameliorate and delay arthritis development and reduce autoimmunity, indicating promising potential of these therapies as a new treatment strategy for RA.

Individualizing therapy of monoclonal antibodies and fusion proteins: emerging potential in the age of personalized medicine.

Personalized medicine is an emerging and promising alternative to standard therapy regimens with the potential to significantly influence therapeutic interventions for many diseases. An extensive literature review of studies that focused on pharmacogenomics of monoclonal antibodies (mAbs) and immunoglobulin-containing fusion proteins (igFPs) was conducted. A comprehensive survey of the US FDA-approved labels revealed that pharmacogenomics information has also been incorporated into the label of some mAbs to guide therapy. In addition, treatment-emergent adverse events for mAbs and igFPs were analyzed that showed an association with the drugs' individual mechanism of action as well as molecular nature. The identification of the signaling pathways linked to the specific target of each mAb or igFP may help accelerate clinical successes in predicting and managing treatment-associated severe adverse events in individual patients. Incorporating pharmacogenomics into drug development of mAbs and igFPs will improve treatment efficacy, and may allow prediction of adverse events. Thus, a promising future of personalized medicine for these therapeutics is predicted.

Combination of alpha-1 antitrypsin and doxycycline suppresses collagen-induced arthritis.

BACKGROUND: Rheumatoid arthritis (RA) is a complex disease characterized by autoimmune inflammation and joint destruction. Despite recent advances in RA treatment, current therapies require further improvement to overcome adverse events and ineffectiveness in some cases. By targeting different pathways/molecules using drug combinations, a better treatment can be obtained, whereas adverse events are reduced. In order to develop a new treatment option, the present study employs a gene therapy-based combination therapy using doxycycline and human alpha-1 antitrypsin (hAAT). METHODS: DBA/1 mice were immunized with type II collagen to induce arthritis. Four weeks before immunization, they received a doxycycline containing diet and a single injection of adeno-associated virus vector expressing hAAT under the control of a tetracycline-dependent promoter. Control groups received doxycycline alone or saline. Macroscopic arthritis development as well as histopathological changes in the joint were evaluated. In addition, the effects of hAAT and doxycycline on lipopolysaccharide (LPS)- or tumor necrosis factor-alpha-induced interleukin (IL)-6 production from mouse fibroblast cells were also determined. RESULTS: Combination therapy significantly reduced arthritis development and progression compared to the control group in respect to macroscopic as well as histopathological changes. Doxycycline and hAAT in combination also inhibited IL-6 expression from LPS-stimulated NIH/3T3 mouse fibroblast cells, indicating a contributing mechanism of arthritis inhibition. CONCLUSIONS: The results obtained in the present study indicate that a combination therapy using AAT and doxycycline holds promising potential as a new therapy for RA.