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| Name | Class |
|---|---|
| University of Cambridge | OTHER |
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Heart failure impacts more than 2% of people in the UK (United Kingdom) and leads to about 5% of emergency hospital visits. Patients might have slowly worsening symptoms or suddenly face acute decompensated heart failure (ADHF), marked by intense difficulty in breathing due to fast-developing lung congestion. This is a serious emergency requiring in-hospital treatment and monitoring. Once stable, patients usually have a phase where symptoms remain constant. But as time goes on, those with heart failure often face more frequent and prolonged episodes of ADHF.
Fluid build-up (pulmonary congestion) in the lungs is a key issue in heart failure, and catching it early helps avoid unexpected hospital stays. Spotting these early signs outside the hospital can be tough, as symptoms aren't always clear. Study investigators are working on a new, non-invasive way to identify these early signs using AI (artificial intelligence) to analyse subtle changes in a patient's voice, cough, and breathing sounds. This tool will act as an early warning for patients and their heart care teams, allowing quicker treatment. This could make heart failure episodes less severe and reduce the need for hospital visits.
This research has two parts. First, a small pilot trial with up to 50 patients. The findings will guide and inform a larger study involving up to 200 patients. From this larger study, investigators will develop the final version of the AI algorithm. The results from the Part A and Part B of this research will guide the investigators in planning a future clinical trial. This trial will confirm if the AI algorithm can be effectively used as a medical tool for heart failure care within the NHS (National Health Service). Study investigators will seek the necessary ethical approval before starting this trial.
Heart failure is a common condition in which the heart is unable to deliver the desired cardiac output either due to a weakened or stiff heart muscle. It affects more than 2% of the UK population (the incidence is around 200,000 cases per annum) resulting in 5% of all the emergency hospital admissions and it consumes approximately 2% of the annual NHS budget (approximately £2 billion per annum). Therefore, heart failure is not only a major driver for hospitalisation but provides the leading opportunity to reduce preventable admissions.
Acute decompensated heart failure (ADHF) is a medical emergency requiring urgent attention. It usually results in inpatient hospitalisation and is a major driver for associated healthcare costs. ADHF is usually characterised by rapid deterioration of breathlessness at rest or exertion because of pulmonary oedema (pulmonary venous congestion), and fluid retention resulting in swollen legs as well as a myriad of other symptoms including fatigue, lack of appetite, and so on.
The patient normally presents with gradual or sudden onset of typical symptoms (breathlessness, fatigue, and fluid accumulation in the legs). After stabilisation and the initial treatment of ADHF, patients enter a plateau phase where the heart remains stable. However, over time, most patients experience multiple episodes of ADHF which typically become longer and separated by shorter intervals. The congestion is related to underlying increased cardiac pressure usually secondary to volume overload which plays a central role in the pathophysiology, presentation, and prognosis of heart failure. Pulmonary congestion is one of the most important diagnostic and therapeutic targets in heart failure. Detecting pulmonary congestion earlier on due to volume overload is key to preventing impending rehospitalisation and presents an ideal opportunity to optimise heart failure treatment in the community.
Early community detection of ADHF is ultimately the first step in providing effective patient care. Poor recognition of HF due to its multitude of vague/non-specific symptomatology of presentations often leads to delays in diagnosis and treatment. The delay between a patient developing symptoms of HF decompensation and seeking medical attention is often considerable and is influenced by the speed of onset and severity of the symptoms. Therefore, a reliable and easily accessible means of assessing chronic fluid status in ambulatory outpatients is needed to detect early decompensation when appropriate intervention is possible. The sudden development of breathlessness (dyspnoea) from the accumulation of fluid in the lungs (acute pulmonary oedema) usually prompts rapid contact with medical services, whereas the gradual appearance of swollen legs and ankles (peripheral oedema) is more likely to be associated with delays in seeking care. The average delay between symptom onset and hospital admission ranged from 2 hours to 7 days. The symptoms of heart failure often develop gradually and appear non-threatening, potentially explaining some of the observed delays in seeking care.
In recent years, several pilot studies demonstrated a relationship between speech biomarkers and the extent of systemic and/or pulmonary congestion in heart failure patients. For example, in 2017, a study of 10 (8 M, 2F) patients with acute decompensated heart failure undergoing inpatient treatment with intravenous diuretic therapy showed that after treatment, patients displayed a higher proportion of automatically identified creaky voice, increased fundamental frequency, and decreased cepstral peak prominence variation, suggesting that speech biomarkers can be early indicators of HF. The study also showed that the severity of HF-related oedema required to measurably change the voice is small compared to the severity needed to increase body weight, suggesting that speech biomarkers could become a more effective non-invasive tool to monitor HF patients than daily weights. In 2021, another study evaluated the feasibility of remote speech analysis in the evaluation of dynamic fluid overload in heart failure patients undergoing hemodynamic treatment. They performed serial speech/voice measurements in 5 patients undergoing haemodialysis. The analysis was done with an app that does not share its AI algorithm. They demonstrated statistically significant differences in select speech biomarkers at different fluid status levels as the patients progressed through the treatment. Subsequently, in 2022, a comparison of sound recordings for patients admitted with ADHF on the day of admission and the day of discharge with a sample of 40 patients who were admitted with acute decompensated heart failure identified significant differences in all 5 tested speech measures of wet (admission) vs dry (discharge) recordings.
Separately, in 2022, a study evaluated speech and pause alterations in voice recordings of acute (N=68) and stable (N=36) patients and found that the pause ratio was a 14.9% increase in patients of acute HF. They also found a positive correlation with NT-Pro-BNP level. Another study in 2022 examined both Mel-Frequency cepstral coefficient (MFCC) features and glottal speech features, comparing a sample of 25 healthy speakers (7F, 18M) and 20 patients with HF of any aetiology (regardless of LVEF). Following feature selection, they developed predictive models using four different classification methods (SVM, ET, Adaboost, and FFNN). Based on a combination of MFCC and Glottal speech features, they were able to predict ADHF with accuracies ranging from 88-94%, with a true positive rate of 79.47% and true negative rate 82.69%.
By performing an extensive panel of clinical assessments, investigations as well as symptom-based questionnaires in a study involving up to 250 heart failure patients, the investigators aim to build upon recent work and develop a novel AI-based application deployed on a smart device, which can detect an increase in pulmonary congestion from subtle changes in a patient's cough, voice, breathing, and chest sounds. This will provide key information for patients with heart failure and their clinical teams, by correctly detecting progressive fluid accumulation in a patient's lungs prior to the patient developing significant symptoms. Detecting early-phase pulmonary congestion will enable clinicians to target therapy more effectively. It is hoped that this will help minimise and ultimately prevent the need for recurrent emergency hospital admission by alerting the patient to contact their (community) heart failure team and enable earlier outpatient treatment prior to the need to be re-hospitalised entering the acute phase.
Subject to the successful outcome of this research, a prospective interventional clinical trial will then be undertaken, to test the clinical and operational benefits of the AI tool derived from this research on NHS heart failure care, paving the way for the eventual adoption of such solutions in routine clinical practice.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Patients with heart failure | Diagnosed with chronic stable heart failure NYHA Class 3 or 4 (either during most recent cardiology/heart failure clinic visit, or ADHF during recent/current hospitalization). |
|
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Height, weight, and BMI | Other | Height, weight measurement and BMI calculation |
|
| Measure | Description | Time Frame |
|---|---|---|
| Area under receiver operating curve (AUC) | The maximum value is "1", describing ability of the AI algorithm to discriminate between dry and congested lungs | Up to 48 months for data collection (includes part A (pilot) + part B (definitive study)) |
| Negative and positive predictive value (NPV and PPV) | NPV and PPV describe the proportions of the positive (congested lungs) and negative (dry lungs) results predicted by the AI algorithm that are true results | Up to 48 months for data collection (includes part A (pilot) + part B (definitive study)) |
| Sensitivity | The ability of the AI algorithm to correctly identify when a heart failure patient has pulmonary congestion | Up to 48 months for data collection (includes part A (pilot) + part B (definitive study)) |
| Specificity | The ability of the AI algorithm to correctly identify when a heart failure patient has no pulmonary congestion (dry lungs) | Up to 48 months for data collection (includes part A (pilot) + part B (definitive study)) |
| Measure | Description | Time Frame |
|---|---|---|
| Weight | Kg | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| NTproBNP | Ng/L | Delta congested (during HF decompensation) vs dry lungs (baseline) |
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Inclusion Criteria:
Exclusion Criteria:
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Patients diagnosed with chronic stable heart failure NYHA Class 3 or 4.
| Name | Role | Phone | Extension | |
|---|---|---|---|---|
| Erdem Demir | Contact | +44 1223 256621 | erdem.demir1@nhs.net | |
| Heike Templin | Contact | +44 1223 250874 | heike.templin@nhs.net |
| Name | Affiliation | Role |
|---|---|---|
| Joseph Cheriyan | Cambridge University Hospitals NHS Foundation Trust | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Cambridge University Hospitals NHS Foundation Trust | Recruiting | Cambridge | Cambridgeshire | CB2 0QQ | United Kingdom |
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| Medical history | Other | Brief medical history including medications/allergies and heart failure related healthcare utilisation over previous 12 months |
|
| Physical examination | Other | Brief physical examination |
|
| Venous blood samples | Diagnostic Test | Venous blood samples, to include WCC, HB, CRP and NTproBNP |
|
| Resting vital signs | Other | HR, BP, RR, oxygen saturations on air) |
|
| Transthoracic echocardiogram | Diagnostic Test | LVEF, IVC collapsibility, LV filling pressure, PA pressure |
|
| Sound recordings | Other | Sound recordings (voice/cough/chest) recorded with the in-built microphone in a smartphone |
|
| Lung ultrasound | Diagnostic Test | Lung ultrasound |
|
| KCCQ questionnaire | Other | Kansas City Cardiomyopathy Questionnaire |
|
| ASCEND-HF score | Other | An in-hospital congestion score which risk stratifies patients admitted with worsening heart failure, developed for the Acute study of clinical effectiveness of Nesiritide in decompensated heart failure trial |
|
| Composite Everest congestion score | Other | A shortened version of the original 18-point score from the EVEREST trial |
|
| Bio impedance and total body water measurement | Diagnostic Test | Bio impedance and total body water measurement using TANITA device |
|
| Heart rate | beats/minute | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Respiratory rate | breaths/min | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Blood pressure | mmHg | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Oxygen saturation (on air) | % | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Left ventricular ejection fraction (ECHO) | % | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Inferior vena cava collapsibility (ECHO) | mm | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Left ventricular filling pressure (ECHO) | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Pulmonary artery pressure | Low, intermediate and High probability with combination of different echo parameters (Tricuspid regurgitation velocity, Pulmonary artery acceleration time, right heart size & pulmonary artery size) | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Speech biomarker - Fundamental frequency | Hz | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Speech biomarker - Jitter and Shimmer | % | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Speech biomarker - Pause duration | ms | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Speech biomarker - Mel Frequency Spectral Coefficients | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| KCCQ (Kansas City Cardiomyopathy Questionnaire) questionnaire | Overall scaled score (0-100) - higher score, better health status. Average scores for each of the domains will also be calculated/ analysed separately | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| ASCEND-HF score | An in-hospital congestion score which risk stratifies patients admitted with worsening heart failure, developed for the Acute study of clinical effectiveness of Nesiritide in decompensated heart failure trial 1-8 (higher score - increased congestion) | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Composite Everest congestion score | A shortened version of the original 18-point score from the EVEREST trial 0-9 (higher score-increased congestion) | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Physiological measures derived from a patient's own pacemaker or CRT device (such as thoracic impedance) | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Bio-Impedance (TANITA) | Ohms | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Total body water (TANITA) | % | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| Number of General Practitioner (GP) reviews | Number of GP reviews for heart failure exacerbations /12 months | 12 months |
| Number of heart failure specialist nurse reviews | Number of heart failure specialist nurse reviews / 12 months | 12 months |
| Number of A&E presentations for heart failure exacerbation | Number of A&E presentations for heart failure exacerbation / 12 months | 12 months |
| Total overnight hospital admissions due to HF exacerbations | Total overnight hospital admissions / 12 months due to heart failure exacerbations | 12 months |
| Total days admitted as inpatient in hospital due to HF exacerbation | Total days admitted as inpatient in hospital due to HF exacerbation over last 12 months | 12 months |
| 8-point method to detect pulmonary congestion (lung US) | Count of B-lines in each of the 8 zones | Delta congested (during HF decompensation) vs dry lungs (baseline) |
| ID | Term |
|---|---|
| D006333 | Heart Failure |
| ID | Term |
|---|---|
| D006331 | Heart Diseases |
| D002318 | Cardiovascular Diseases |
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| ID | Term |
|---|---|
| D001827 | Body Height |
| D014894 | Weights and Measures |
| D015992 | Body Mass Index |
| D055991 | Health Records, Personal |
| D012149 | Restraint, Physical |
| D004452 | Echocardiography |
| D000087983 | Sound Recordings |
| ID | Term |
|---|---|
| D049628 | Body Size |
| D001837 | Body Weights and Measures |
| D001824 | Body Constitution |
| D010808 | Physical Examination |
| D019937 | Diagnostic Techniques and Procedures |
| D003933 | Diagnosis |
| D000067029 | Physical Appearance, Body |
| D000886 | Anthropometry |
| D008919 | Investigative Techniques |
| D010829 | Physiological Phenomena |
| D006128 | Growth |
| D048788 | Growth and Development |
| D001699 | Biometry |
| D015991 | Epidemiologic Measurements |
| D011634 | Public Health |
| D004778 | Environment and Public Health |
| D008499 | Medical Records |
| D011996 | Records |
| D003625 | Data Collection |
| D004812 | Epidemiologic Methods |
| D032763 | Behavior Control |
| D013812 | Therapeutics |
| D007103 | Immobilization |
| D057791 | Cardiac Imaging Techniques |
| D003952 | Diagnostic Imaging |
| D014463 | Ultrasonography |
| D006334 | Heart Function Tests |
| D003935 | Diagnostic Techniques, Cardiovascular |
| D001296 | Audiovisual Aids |
| D018961 | Educational Technology |
| D013672 | Technology |
| D013676 | Technology, Industry, and Agriculture |
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