Clinical Trial Details
— Status: Withdrawn
Administrative data
NCT number |
NCT05288413 |
Other study ID # |
IRAS313321 |
Secondary ID |
|
Status |
Withdrawn |
Phase |
|
First received |
|
Last updated |
|
Start date |
March 1, 2022 |
Est. completion date |
August 1, 2022 |
Study information
Verified date |
January 2023 |
Source |
Imperial College London |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Observational
|
Clinical Trial Summary
The study coordinator aims to compare gold standard deep vein thrombosis (DVT) diagnostic
performed by a specialist sonographer to a scan by a non-specialist with a newly developed an
automated DVT (AutoDVT) detection software device.
The title of the project is: Benefit of Machine learning to diagnose Deep Vein thrombosis
compared to gold standard Ultrasound.
Currently the process from the DVT symptom begin, to diagnosis and then treatment is all but
not straightforward. It implements a laborious journey for the patient from their general
practitioner (GP) to accident and emergency (A&E), then to a specialist sonographer.
However, handheld Ultrasound devices have recently become available and they have been
implemented with a machine learning software. The startup company ThinkSono developed a
software which is hoped to divide between thrombosis and no thrombosis. In this
single-blinded pilot study, patients which present at St Mary's DVT Clinic will be scanned by
the specialist and then by a non-specialist with the machine learning supported device. The
accuracy and sensitivity of this device will be compared to the gold standard.
This would mean that DVT could be diagnosed at point of care by a non-specialist such as a
community nurse or nursing home nurse, for example beneficial for multimorbid confused
nursing home patients. This technology could reduce A&E crowding and free up specialist
sonographer to focus on other clinical tasks. These improvements could significantly reduce
the financial burden for the National Health System (NHS).
The AutoDVT has a CE (as the logo CЄ, which means that the manufacturer or importer affirms
the good's conformity with European health, safety, and environmental protection standards)
Certificate under the directive 93/42/ European Economic Community (EEC) for medical devices.
It is classified in Class 1 - Active Medical Device - Ultrasound Imaging System Application
Software (40873).
Furthermore, following standards and technical specifications have been applied: British
Standard (BS) European Norm (EN) International Organisation for Standardisation (ISO)
13485:2016, BS EN ISO 14971:2012, Data Coordination Board (DCB)0129:2018, ISO 15233-1:2016.
Description:
"AutoDVT" is a software system designed to assist non-specialist operators, such as nurses,
general practitioners (GP) and other allied health professionals in the diagnosis of DVT. The
software utilises a "machine learning" algorithm as described below.
This study aims to improve the current laborious, time consuming and expensive diagnostic DVT
pathway.
Venous thrombosis (VT) commonly occurs in the deep leg veins as well as the deep veins of the
pelvis. DVTs can be divided into above knee (iliac, femoral, popliteal) and below knee (calf
veins).
DVT is well recognised to cause globally significant morbidity and mortality both at the time
of diagnosis and post-diagnosis. Between 30 - 50 percent of patients diagnosed with DVT will
go on to develop a post-thrombotic syndrome, which has a significant impact on patients'
long-term quality of life. Patients with DVT are also at risk to develop a fatal pulmonary
embolism (PE). According to Charity Thrombosis United Kingdom (UK) dies every 37 seconds a
person of a VT in developed countries.
Between 75-88 percent of suspected DVT cases, when fully investigated, are negative. The cost
for diagnosing DVT over a decade ago was between 42-202 British Pound (£), such that the cost
to the NHS of investigating all patients who present with DVT symptoms was approximately £175
million annually as stated in the study 'Non-invasive diagnosis of deep vein thrombosis from
ultrasound imaging with machine learning' by Prof. Kainz from Imperial College London.
It is important to note that this value does not take into account any additional indirect
costs such as time lost from work, hospitalisation, treatment costs and costs for repeat
ultrasound scans. It is difficult to diagnose a DVT by clinical exam alone. The current
standard approach to diagnose a proximal DVT involves an algorithm combining pre-test
probability (Wells Score), D-dimer (blood) testing, and compression ultrasonography
(typically a three-point compression examination).
There are new handheld ultrasound (US) probes available, meaning only the US probe is
required for diagnostic purposes in conjunction with a mobile phone or tablet. At present,
although the new handheld probes are smaller and are better suited for point of care
diagnosis, they still require an experienced radiologist or sonographer to perform the
three-point compression exam.
This means, that these devices can only be used wherever specialists such as radiographers or
radiologists are based. However, due to recent advances in "machine learning", a software has
now been developed for these 'app-based' probes that can assist non-specialist healthcare
professionals to carry out the compression US exam with minimal training and divide between
DVT and not DVT.
The previous data-collecting study for this device at Oxford University Hospital (OUH) was
primarily used to improve the AutoDVT software but it also highlighted in a small pilot study
that this technology had a similar diagnostic test accuracy to standard compression US. The
study outlined in this protocol will test this hypothesis.