In the not so distant past, the typical clinical trial site operated with one physician, nurse, and dedicated exam room. Now, most sites employ many clinicians and a group of exam rooms with different devices.
In this more complex environment we need to explore new tools that can help us visualise what is happening at sites so that we can analyse the root cause of problems. Many of these errors do not stem from training issues, but rather factors that can be more difficult to analyse at face value. Increasingly common error sources — such as inefficient processes, cultural factors, or deficient IT support — require a different approach to identify and interpret the causes.
Furthermore, CRAs need to be able to prioritise the errors that matter; not necessarily those that occur once, but recurrent errors that affect patient and trial outcomes.
Because not all sites and protocols carry equal risk, traditional monitoring (100% SDV and regularly scheduled site visits) can utilise resources on low risk sites while preventing the CRA from intensifying effort on high-risk sites. Implementing 100% SDV does not prevent errors from occurring. In a TransCelerate study to determine the effectiveness of 100% SDV and its impact on overall data quality, only 7.8% of total queries and 2.4% of critical data queries were generated as a result of 100% SDV. These data suggest that a primary focus on data verification has a “negligible effect” on improving data quality.
To prevent the recurrence of errors that matter most to patients, CRAs need the tools to approach monitoring data from a new perspective.
Extending modern monitoring practices with patient centricity
Fixing a mistake is more effective if its source is known and understood. We’ve already discussed how other industries, such as aviation, identify and fix errors through classification of the human factors that contributed to serious incidents. Likewise, in clinical trials, visualisation tools and a systematic approach to error classification reveal hard-to-discern trends can vastly improve a CRA’s ability to identify, track, and mitigate risk that impact patients.
Consider a CRA who is responsible for monitoring 16 sites. This CRA’s time could be focused empirically on the most serious threats to trial integrity by visualising error incidence by site (Figure 1, below). We can see that site P has a large number of errors, but do all of those errors have the same cause?
These errors, in traditional monitoring approaches, would be addressed through a CRA retraining sites regardless of the type and severity of errors. The problem is that retraining can only address errors that occurred as a result of improper training. Errors that result from missteps in the execution of process (process errors) or from lack of communication will continue to propagate despite retraining.
However, using Human Factors Classification (HFC) to identify the root cause of site errors, the CRA can visualise a breakdown of the error sources at site P (Figure 1, below). He or she can then put in place pre-bespoke mitigation strategies to address each error in a way that will be more successful than simply retraining the site staff.
In this case, site P was identified as underreporting concomitant medication. The CRA confirmed at the site monitoring visit that adverse event (AE) and concomitant medications were recorded in source or hand-written logs, but the data were not entered into the EDC system. With the traditional approach, a CRA might retrain on proper usage of the EDC system.
Using HFC, however, the CRA dug deeper to find out the root cause and principal human factor for the problem. During root cause investigation the CRA also discovered three additional, previously undetected issues:
- Laboratory values meeting AE criteria were not entered in the EDC system and were not assessed in a timely manner by the Primary Investigator
- Source documentation did not contain additional information regarding causality, stop dates or dose for AEs, and frequency and dates for concomitant medication
- Source notes and logs were discrepant
Through the HFC analysis, the root cause and principal human factor for the finding was identified as the lack of a consistent process for data oversight and record keeping at this site. The Principal Investigator was asked to develop and implement a specific AE and concomitant medication handling and reporting process. Retraining on the use of the EDC would never have resolved this issue.
Impact
There are obvious benefits to classifying and visualising risk in clinical trials, particularly through access to analytics and trends that demonstrate what is and is not working in the trial.
A far greater, but perhaps less quantifiable benefit, is likely to be improved CRA effectiveness. Instead of performing 100% SDV, CRAs strategically analyse risk, make decisions on necessary corrective actions, know why they are performing a corrective action, and ultimately realise how important their role is in ensuring the trial runs smoothly.
This style of leadership, known in the military as mission command, has been shown to be significantly more effective than when subordinates follow orders from their leadership without receiving insight about the importance of their job, which the military calls command and control.
Moving away from 100% SDV to a patient centric monitoring approach based on the root human causes of error is worth considering. Seven of our pharmaceutical and biotechnology partners are now employing HFC in their trials to generate material benefits in cost efficiency and quality.
In this section
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Digital Disruption
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Clinical trial data anonymisation and data sharing
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Clinical Trial Tokenisation
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Closing the evidence gap: The value of digital health technologies in supporting drug reimbursement decisions
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Digital disruption in biopharma
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Disruptive Innovation
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Personalising Digital Health
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The triad of trust: Navigating real-world healthcare data integration
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Patient Centricity
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Agile Clinical Monitoring
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Capturing the voice of the patient in clinical trials
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Charting the Managed Access Program Landscape
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Developing Nurse-Centric Medical Communications
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Exploring the patient perspective from different angles
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Patient safety and pharmacovigilance
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A guide to safety data migrations
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Taking safety reporting to the next level with automation
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Outsourced Pharmacovigilance Affiliate Solution
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The evolution of the Pharmacovigilance System Master File: Benefits, challenges, and opportunities
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Sponsor and CRO pharmacovigilance and safety alliances
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Understanding the Periodic Benefit-Risk Evaluation Report
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A guide to safety data migrations
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Patient voice survey
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Patient Voice Survey - Decentralised and Hybrid Trials
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Reimagining Patient-Centricity with the Internet of Medical Things (IoMT)
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Using longitudinal qualitative research to capture the patient voice
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Agile Clinical Monitoring
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Regulatory Intelligence
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An innovative approach to rare disease clinical development
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Using innovative tools and lean writing processes to accelerate regulatory document writing
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Current overview of data sharing within clinical trial transparency
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Global Agency Meetings: A collaborative approach to drug development
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Keeping the end in mind: key considerations for creating plain language summaries
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Navigating orphan drug development from early phase to marketing authorisation
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Procedural and regulatory know-how for China biotechs in the EU
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RACE for Children Act
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Early engagement and regulatory considerations for biotech
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Requirements & strategy considerations within clinical trial transparency
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Spotlight on regulatory reforms in China
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An innovative approach to rare disease clinical development
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Crossing the finish line: Why effective participation support strategy is critical to trial efficiency and success in rare diseases
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Diversity, equity and inclusion in rare disease clinical trials
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Identify and mitigate risks to rare disease clinical programmes
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Leveraging historical data for use in rare disease trials
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Natural history studies to improve drug development in rare diseases
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Patient Centricity in Orphan Drug Development
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The key to remarkable rare disease registries
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Therapeutic spotlight: Precision medicine considerations in rare diseases
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Advanced therapies for rare diseases
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Transforming Trials
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Ensuring the validity of clinical outcomes assessment (COA) data: The value of rater training
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Linguistic validation of Clinical Outcomes Assessments
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Biopharma perspective: the promise of decentralised models and diversity in clinical trials
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Decentralised and Hybrid clinical trials
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Practical considerations in transitioning to hybrid or decentralised clinical trials
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Navigating the regulatory labyrinth of technology in decentralised clinical trials
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Biopharma perspective: the promise of decentralised models and diversity in clinical trials
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Implications of COVID-19 on statistical design and analyses of clinical studies
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Increasing Complexity and Declining ROI in Drug Development
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Transforming the R&D Model to Sustain Growth
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Payer Reliance on ICER and Perceptions on Value Based Pricing
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Payers Perspectives on Digital Therapeutics
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RWE Generation Cross Sectional Studies and Medical Chart Review
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Survey results: How to engage healthcare decision-makers
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