Artificial Intelligence to Improve Detection and Risk Stratification of Acute Pulmonary Embolism (AID-PE)

Recruiting

• Conditions: Pulmonary Embolism
• Interventions: Device: Artificial Intelligence

• Registration Number: NCT06093217
• Lead Sponsor: Royal United Hospitals Bath NHS Foundation Trust

Brief Summary

The goal of this exploratory observational study is to assess the feasibility and real-world clinical impact of implementing Artificial Intelligence (AI) software for the detection of acute Pulmonary Embolism (PE) in patients who undergo Computed Tomography Pulmonary Angiogram (CTPA). The main questions that this study aims to answer are:

\[Question 1\] What is the real-world impact of AI on the clinical outcomes and decision making by radiologists and clinicians in the management of acute PE?

\[Question 2\] Is AI software for the detection of acute PE acceptable to use in clinical practice and do they have a favourable impact on clinical workload?

\[Question 3\] Is it cost-effective to implement AI software for the detection of acute PE in clinical practice?

Patients having a CTPA for the detection of acute PE will have their imaging analysed by AI software in combination with a human radiologist. Researchers will aim to compare the clinical and radiology specific outcomes with a retrospective cohort of patients who have had standard routine radiology reporting.

Detailed Description

Acute Pulmonary Embolism (PE) results from partial or total occlusion of the pulmonary blood vessels by thrombus, which can cause right ventricular failure and death if not diagnosed and treated early. Acute PE is a common condition with rising mortality. Patients with acute PE are often poorly risk stratified despite clear guidelines. In fact, the 2019 National Confidential Inquiry into Patient related Outcome and Death (NCEPOD) for acute PE highlighted the need to address worsening mortality rates through appropriate risk stratification of the condition.

ESC/ERS guidelines for the diagnosis and management of acute PE also advise on the importance of risk stratification. An increased right ventricle: left ventricle (RV:LV) ratio \>1.0 on Computed Tomography Pulmonary Angiogram (CTPA) is associated 2.5-fold increased risk of all-cause mortality, and 5-fold risk for PE-related mortality. This metric is intended to help clinicians distinguish between patients with high and low risk acute PE. Patients stratified as high risk (RV:LV ratio \>1.0) necessitate closer monitoring within an inpatient setting. Whereas, patients stratified as low risk (RV:LV ratio \<1.0) are suitable for early discharge through ambulatory pathways.

Therefore, the provision of RV:LV metrics within radiology reporting has potentially important clinical implications. If clinicians are not provided with any quantifiable evidence of RV dysfunction on which to base their treatment decisions, patients with high risk acute PE may be unintentionally considered 'low risk' and discharged home. Furthermore, patients with low risk acute PE may be subject to longer, and potentially unnecessary, inpatient stays which undoubtedly contributes to the cost of healthcare. The integration of Artificial Intelligence (AI) technology within radiology reporting of CTPAs for acute PE could be a potential solution to address this challenge.

AI is an increasingly attractive technology within healthcare. It describes a number of computer software techniques which mimic human cognitive function. AI shows promise in ability to detect and risk stratify acute PE. However, most studies have been conducted in retrospective cohorts. Furthermore, no study current has addressed the health economic impact of implementing AI technology within the real-world reporting of acute PE.

This observational study will be led by Royal United Hospital Bath NHS Trust (RUH). The aim of this study is to integrate Artificial Intelligence and machine learning technology within the reporting of CTPAs for acute PE. The investigators hypothesise that AI technology can improve the prompt diagnosis, risk stratification, and management of acute PE within a real-world clinical setting. The investigators also hypothesis that integration of AI technology is cost-effective, and acceptable to radiologists and clinicians.

Patients whose scans will be included in the study will be all those consecutively presenting to the RUH with a possible diagnosis of acute PE for 12 months before (comparator cohort) and 12 months after (intervention cohort) 'live' introduction of integrated AI technology reporting. For all recruited participants, an anonymised clinician case report form will be used to capture details relating to their demographics, clinical-radiological PE severity, their management, and outcomes including mortality at 12 months.

At the point of analysis, the investigators will perform adjustments/matching between the two cohorts for patient baseline characteristics. The investigators will also adjust for calendar time of recruitment, to account for temporal trends. Analysis between both cohorts will also allow development of a decision analysis model to assess the cost-effectiveness of integrated AI technology within CTPA report for acute PE. Clinician and radiologist questionnaires will be used to assess user acceptability.

Study Timeline

• Status Verified: 2023-10
• Study First Submitted: 2023-10-04
• Study First Submitted QC: 2023-10-16
• Study First Posted: 2023-10-23
• Study Start: 2024-01-08
• Last Update Submitted: 2024-04-09
• Last Update Posted: 2024-04-10
• Primary Completion: 2025-01-31
• Study Completion: 2025-12-31

Recruitment & Eligibility

• Status: RECRUITING
• Sex: All
• Target Recruitment: 2500

Inclusion Criteria

• Patients over 18 years of age
• Patient requiring CTPA to exclude or diagnose acute PE

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Exclusion Criteria

• Patients under 18 years of age
• Patients who have registered with the national opt-out scheme for research
• CTPA performed for reasons other than acute PE
• CTPA performed for acute PE but reported by external radiologists
• Incomplete or discontinued CTPA scans
• Insufficient quality CTPA to allow for analysis by a radiologist

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Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Arm && Interventions

Group	Intervention	Description
Comparator Cohort: Standard Radiology reporting	Artificial Intelligence	Retrospective CTPAs, for patients with suspected acute PE, which have been reported by a human radiologist only. These CTPAs will not be interpreted by AI technology 'live' BUT undergo analysis to help assess the sensitivity, specificity, false negative, false positive rates of AI technology.
Prospective Cohort: 'Live' Introduction of AI technology	Artificial Intelligence	Consecutive CTPAs, for patients with suspected acute PE, which have their imaging interpreted 'live' by AI technology. The radiologist will have ultimate responsibility for the report generated.

Primary Outcome Measures

Name	Time	Method
Proportion of patient decisions made in line with evidence based best practice guidelines after introducing AI technology within CTPA reporting	12 months	Comparison before and after AI introduction

Secondary Outcome Measures

Name	Time	Method
Rate of acute PE detection with AI technology	24 months	True positives and True negatives
Rate of discordant acute PE cases	24 months	False positive and false negative rate with acute PE detection
AI failure rate for acute PE detection	24 months	Proportion of scans unable to be interpreted by AI despite suitable CTPA acquisition
Time to anticoagulation in PE cases	12 months	Comparison before and after AI introduction
Cost to NHS for acute PE	12 months	Comparison before and after AI introduction
Rate of RV:LV detection with AI technology	24 months	True positive and true negative
Failure rate for automated RV:LV ratio	24 months	Proportion of scans unable to calculate automated RV:LV ratio despite suitable CTPA acquisition
30 day mortality	12 months	Patient mortality (death) at 30-days post-PE diagnosis. Comparison before and after AI introduction.
Time from CTPA to discharge	12 months	Comparison before and after AI introduction
Rate of discordant RV:LV detection	24 months	False positive and false negative
12 month mortality	12 months	Patient mortality (death) at 12-months post-PE diagnosis. Comparison before and after AI introduction.
Hospital admission and bed days for acute PE	12 months	Comparison before and after AI introduction
End-user (clinician and radiologist) acceptability of AI technology	12 months	Quantified metrics from a non-validated questionnaire to evaluate end-use experience of integrated AI radiology reporting.
Referral rates to outpatient follow-up (respiratory, thrombosis, haematology)	12 months	Comparison before and after AI introduction
PE risk stratification rates (low, intermediate low, intermediate high and high risk)	12 months	Comparison before and after AI introduction
Diagnostic rate of Chronic thromboembolic pulmonary hypertension (CTEPH)	12 months	Comparison before and after AI introduction

Trial Locations

Locations (1)

Royal United Hospitals, Bath NHS Foundation Trust; 🇬🇧 Bath, United Kingdom