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In the current US organ transplantation system, there are no regulations defining how organ procurement organizations must manage personal data and protect the privacy of donors and recipients. In response to the recent announcement of a major overhaul of the US transplantation system, we describe a practical approach to improving transplant data quality and protecting the autonomy of patients interacting with the system.
ABSTRACT
Non-communicable diseases, such as cancer, diabetes, and chronic cardiovascular and respiratory diseases, remain a major cause of mortality and morbidity worldwide resulting in more than 36 million deaths annually. Of primary importance in the reduction of this pain and suffering is the local use of education to eliminate misconception, enable prevention, reduce the associated social stigmas, and prepare a workforce that can care for its own people as well as feed an economic engine helping to combat the poverty that so often determines the availability and quality of care. The need to develop these local capabilities is especially acute for children, as 80% of pediatric cancer cases occur in low- and middle-income countries, places where the survival rates are lowest.
Subject(s)
Health Education , Internationality , Neoplasms/prevention & control , Child , Community Networks , Humans , Neoplasms/psychology , Primary Prevention , Social StigmaABSTRACT
Understanding privacy in the digital age requires a deep understanding of the forces driving the internet and the specific resulting harms. To protect patients in digitized clinical trials, we must look beyond the traditional and historical concept of medical privacy.
Subject(s)
Clinical Trials as Topic , Privacy , Computer Security , Humans , InternetABSTRACT
Importance: Emerging policies drafted by the pharmaceutical industry indicate that they will transparently share clinical trial data. These data offer an unparalleled opportunity to advance evidence-based medicine and support decision-making. Objective: To evaluate the eligibility of independent, qualified researchers to access individual participant data (IPD) from oncology trials that supported US Food and Drug Administration (FDA) approval of new anticancer medicines within the past 10 years. Design, Setting, and Participants: In this quality improvement study, a cross-sectional analysis was performed of pivotal clinical trials whose results supported FDA-approved anticancer medicines between January 1, 2011, and June 30, 2021. These trials' results were identified from product labels. Exposures: Eligibility for IPD sharing was confirmed by identification of a public listing of the trial as eligible for sharing or by receipt of a positive response from the sponsor to a standardized inquiry. Main Outcomes and Measures: The main outcome was frequency of IPD sharing eligibility. Reasons for data sharing ineligibility were requested and collated, and company-, drug-, and trial-level subgroups were evaluated and presented using χ2 tests and forest plots. Results: During the 10-year period examined, 115 anticancer medicines were approved by the FDA on the basis of evidence from 304 pharmaceutical industry-sponsored trials. Of these trials, 136 (45%) were eligible for IPD sharing and 168 (55%) were not. Data sharing rates differed substantially among industry sponsors, with the most common reason for not sharing trial IPD being that the collection of long-term follow-up data was still ongoing (89 of 168 trials [53%]). Of the top 10 anticancer medicines by global sales, nivolumab, pembrolizumab, and pomalidomide had the lowest eligibility rates for data sharing (<10% of trials). Conclusions and Relevance: There has been a substantial increase in IPD sharing for industry-sponsored oncology trials over the past 5 years. However, this quality improvement study found that more than 50% of queried trials for FDA-approved anticancer medicines were ineligible for IPD sharing. Data accessibility would be substantially improved if, at the time of FDA registration of a medicine, all data that support the registration were made available.
Subject(s)
Antineoplastic Agents , Neoplasms , Antineoplastic Agents/therapeutic use , Cross-Sectional Studies , Drug Approval , Humans , Information Dissemination , Neoplasms/drug therapy , Nivolumab , Pharmaceutical Preparations , United States , United States Food and Drug AdministrationABSTRACT
BACKGROUND: The growing consensus that most valuable data source for biomedical discoveries is derived from human samples is clearly reflected in the growing number of translational medicine and translational sciences departments across pharma as well as academic and government supported initiatives such as Clinical and Translational Science Awards (CTSA) in the US and the Seventh Framework Programme (FP7) of EU with emphasis on translating research for human health. METHODS: The pharmaceutical companies of Johnson and Johnson have established translational and biomarker departments and implemented an effective knowledge management framework including building a data warehouse and the associated data mining applications. The implemented resource is built from open source systems such as i2b2 and GenePattern. RESULTS: The system has been deployed across multiple therapeutic areas within the pharmaceutical companies of Johnson and Johnsons and being used actively to integrate and mine internal and public data to support drug discovery and development decisions such as indication selection and trial design in a translational medicine setting. Our results show that the established system allows scientist to quickly re-validate hypotheses or generate new ones with the use of an intuitive graphical interface. CONCLUSIONS: The implemented resource can serve as the basis of precompetitive sharing and mining of studies involving samples from human subjects thus enhancing our understanding of human biology and pathophysiology and ultimately leading to more effective treatment of diseases which represent unmet medical needs.
Subject(s)
Health Knowledge, Attitudes, Practice , Information Management , Translational Research, Biomedical/organization & administration , Biomarkers, Tumor/metabolism , Humans , Meta-Analysis as Topic , Models, Biological , Neoplasms/genetics , Neoplasms/pathology , Reproducibility of Results , Search Engine , SoftwareABSTRACT
Wearable digital devices offer potential advantages over traditional methods for the collection of health-related information, including continuous collection of dense data while study subjects are ambulatory or in remote settings. We assessed the utility of collecting continuous actigraphy and cardiac monitoring by deploying two US Food and Drug Administration (FDA) 510(k)-cleared devices in a phase I clinical trial of a novel compound, which included the use of an amphetamine challenge. The Phillips Actiwatch Spectrum Pro (Actiwatch) was used to assess mobility and sleep. The Preventice BodyGuardian (BodyGuardian) was used for monitoring heart rate (HR) and respiratory rate (RR), via single-lead electrocardiogram (ECG) recordings, together with physical activity. We measured data collection rates, compared device readouts with conventional measures, and monitored changes in HR measures during the amphetamine challenge. Completeness of data collection was good for the Actiwatch (96%) and lower for the BodyGuardian (80%). A good correlation was observed between device and in-clinic measures for HR (r = 0.99; P < 0.001), but was poor for RR (r = 0.39; P = 0.004). Manual reviews of selected ECG strips corresponding to HR measures below, within, and above the normal range were consistent with BodyGuardian measurements. The BodyGuardian device detected clear HR responses after amphetamine administration while subjects were physically active, whereas conventional measures collected at predefined timepoints while subjects were resting and supine did not. Wearable digital technology shows promise for monitoring human subjects for physiologic changes and pharmacologic responses, although fit-for-purpose evaluation and validation continues to be important prior to the wider deployment of these devices.
Subject(s)
Actigraphy/instrumentation , Amphetamine/administration & dosage , Electrocardiography, Ambulatory/instrumentation , Exercise/physiology , Heart Rate/drug effects , Wearable Electronic Devices , Actigraphy/methods , Adult , Electrocardiography, Ambulatory/methods , Feasibility Studies , Heart Rate/physiology , Humans , Male , Middle Aged , Respiratory Rate/drug effects , Respiratory Rate/physiologyABSTRACT
We assessed the performance of two US Food and Drug Administration (FDA) 510(k)-cleared wearable digital devices and the operational feasibility of deploying them to augment data collection in a 10-day residential phase I clinical trial. The Phillips Actiwatch Spectrum Pro (Actiwatch) was used to assess mobility and sleep, and the Vitalconnect HealthPatch MD (HealthPatch) was used for monitoring heart rate (HR), respiratory rate (RR), and surface skin temperature (ST). We measured data collection rates, compared device readouts with anticipated readings and conventional in-clinic measures, investigated data limitations, and assessed user acceptability. Six of nine study participants consented; completeness of data collection was adequate (> 90% for four of six subjects). A good correlation was observed between the HealthPatch device derived and in-clinic measures for HR (Pearson r = 0.71; P = 2.2e-16) but this was poor for RR (r = 0.08; P = 0.44) and ST (r = 0.14; P = 0.14). Manual review of electrocardiogram strips recorded during reported episodes of tachycardia > 180 beats/min showed that these were artefacts. The HealthPatch was judged to be not fit-for-purpose because of artefacts and the need for time-consuming manual review. The Actiwatch device was suitable for monitoring mobility, collecting derived sleep data, and facilitating the interpretation of vital sign data. These results suggest the need for fit-for-purpose evaluation of wearable devices prior to their deployment in drug development studies.
Subject(s)
Wearable Electronic Devices , Actigraphy , Adolescent , Adult , Circadian Rhythm/physiology , Electrocardiography , Feedback , Female , Heart Rate , Humans , Male , Middle Aged , Respiratory Rate , Skin Temperature , Sleep/physiology , Vital Signs , Young AdultABSTRACT
Conducting research in a humanitarian setting requires quantifiable quality measures to ensure ethical study conduct. Digital health technologies are proven to improve research study quality and efficacy via automated data collection, improvement of data reliability, fidelity and resilience and by improved data provenance and traceability. Additionally, digital health methodologies can improve patient identity, patient privacy, study transparency, data sharing, competent informed consent, and the confidentiality and security of humanitarian operations. It can seem counterintuitive to press forward aggressively with digital technologies at a time of heightened population vulnerability and cyber security concerns, but new approaches are essential to meet the rapidly increasing demands of humanitarian research. In this paper we present the case for the digital modernization of humanitarian research in conflict and other humanitarian settings as a vehicle for improved research quality and ethics.
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The development of innovative wearable technologies has raised great interest in new means of data collection in healthcare and biopharmaceutical research and development. Multiple applications for wearables have been identified in a number of therapeutic areas; however, researchers face many challenges in the clinic, including scientific methodology as well as regulatory, legal, and operational hurdles. To facilitate further evaluation and adoption of these technologies, we highlight methodological and logistical considerations for implementation in clinical trials, including key elements of analytical and clinical validation in the specific context of use (COU). Additionally, we provide an assessment of the maturity of the field and successful examples of recent clinical experiments.
Subject(s)
Clinical Trials as Topic , Wearable Electronic Devices , Actigraphy , Blood Pressure Monitoring, Ambulatory , Data Collection , Electrocardiography, Ambulatory , Electroencephalography , Galvanic Skin Response , Humans , Medication Adherence , Mobile Applications , Oximetry , Skin Temperature , SmartphoneABSTRACT
Virtually all health care organizations have had at least one data breach since 2012. Most of the largest data breaches and Health Care Information Privacy and Accountability Act fines could have been prevented by the simplest of strategies. Each researcher must clearly understand his or her responsibilities and liability.
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Computer Security , Translational Research, Biomedical , Electronic Health Records , Humans , Risk ManagementABSTRACT
Many things have changed but much has remained the same as we have seen a dramatic increase in the generation of genetics, genomics and a variety of clinical data leading to increased data density and continued challenges in organizing and managing that data in pursuit of personalized medicine. Simultaneously, we have seen an increase in commercial and open-source solutions, and marked movement toward open sharing of tools and data in public-private partnerships, yet still few examples of traditional companion diagnostics for personalized medicine products. Most encouraging are examples of focused public and private efforts that have resulted in knowledge leading to critical assessment of existing therapies and the development of new therapies. These examples lay highly emulatable informatics foundations for rapid advances in personalized medicine.
Subject(s)
Computers , Data Mining , Databases as Topic , Computer Security , Diffusion of Innovation , Humans , Information Systems , Patient-Centered CareABSTRACT
Personalized medicine is often associated and discussed in the context of advances from the human genome project. It is true that significant breakthroughs and advancement of deep sequencing and other analytical technologies have greatly expanded the pool of available biological data, but integrating this data into medically meaningful knowledge via translational informatics remains an area of opportunity that is far from being fully realized. Significant opportunities remain for informatics to drive progress towards wide use and utility of personalized medicine by focusing and exploitation of multimodal biomarkers, precompetitive data sharing and a balance between high-content data and rich phenotypic data, such as real observational medical outcomes.