Heart Failure Clinical Trial
Official title:
Pacemaker Induced Transient Dyssynchrony for Treating Heart Failure (PITA-HF): Feasibility, Safety, and Tolerability
Verified date | December 2022 |
Source | Johns Hopkins University |
Contact | n/a |
Is FDA regulated | No |
Health authority | |
Study type | Interventional |
Heart failure affects over 25 million people worldwide and nearly 7 million adults in the United States alone. Nearly 25% of patients with heart failure have worsened disease burden from dyssynchronous ventricular contraction due to abnormal electrical impulse propagation. These patients may benefit from cardiac resynchronization therapy (CRT) where contraction between the ventricles is coordinated by simultaneous electrical stimulation of the right and left ventricles. In animal models, CRT changes molecular and cellular biology by improving myofilament function, ion channel regulation, beta-receptor signaling, and overall mitochondrial energetics. In randomized clinical outcomes trials, the use of CRT further reduced the incidence of heart failure events and improved overall mortality. However, nearly 75% of patients with heart failure have synchronous ventricular contraction and therefore do not qualify for CRT. CRT profoundly alters underlying molecular and cellular biology as a result of the transition from dyssynchronous to resynchronized contraction, enhancing myocyte function and adrenergic responsiveness. The investigators previously hypothesized CRT-like benefits could be achieved in otherwise synchronous heart failure by purposely inducing dyssynchrony for several hours each day and then reversing this for the remainder of the time. The investigators termed this pacemaker induced transient dyssynchrony, or PITA, and tested its impact in a canine dilated cardiomyopathy model. Following several weeks of rapid atrial pacing to induce heart failure in the animals, the investigators compared implementing 4-weeks of PITA - consisting of dyssynchronous rapid right ventricular pacing for 6 hours each night and atrial pacing for the remaining time - to animals that always received rapid atrial pacing. The fast rate is used to generate a heart failure phenotype. PITA improved chamber dilation, increased beta-adrenergic responsiveness and contractile function, and improved myofiber structure compared to heart failure canine controls. While first tested in an intact conscious translational model, no study has yet investigated PITA in humans. This pilot research protocol tests the feasibility, safety, and tolerability of PITA in humans with dilated cardiomyopathy. The study will leverage pre-existing Medtronic (Mounds View, MN) pacemaker/defibrillators implanted in dilated cardiomyopathy patients based on current clinical guidelines. If successful, this study will allow for a larger, first-in-human study to assess indexes of left ventricular function in dilated cardiomyopathy patients with PITA.
Status | Completed |
Enrollment | 8 |
Est. completion date | February 1, 2023 |
Est. primary completion date | February 1, 2023 |
Accepts healthy volunteers | No |
Gender | All |
Age group | 18 Years and older |
Eligibility | Inclusion Criteria: - Patient =18 years of age - Ejection fraction of <40% by noninvasive testing (TTE, nuclear stress, cardiac MRI) within 6 months of study enrollment - Presence of Medtronic device (single chamber ICD or dual chamber ICD) with Sleep Function feature (Models: Evera, Maximo II, Virtuoso II, Secura, Protecta) - Low pacing burden, defined as <5% RV pacing in the prior month as determined by baseline device interrogation (prior to Week 0) - Narrow QRS complex (<100 milliseconds) on baseline ECG without any pacing or with atrial pacing only - No evidence of incomplete bundle branch block or intraventricular conduction delay, defined as QRS 100-120 milliseconds with: a. S wave in V1 with broad R waves in I, aVL, and V6 b. RSR' in v1 with terminal S waves in I, aVL, and V6 c. not meeting patterns in a or b but with QRS complex 100-120 milliseconds - No indications for CRT-D upgrade at time of enrollment - Followed by a physician for treatment of heart failure - Currently receiving guideline-directed medical therapy for HFrEF - No changes in diuretic over the past 30 days - Willingness to provide informed consent - Negative pregnancy test in a female of child bearing potential Exclusion Criteria: - Age <18 years - Ejection fraction >40% by noninvasive testing in the preceding 12 months - Acute coronary syndrome within 4 weeks as defined by electrocardiographic (ECG) ST-segment depression or prominent T-wave inversion and/or positive biomarkers of necrosis (e.g., troponin) in the absence of ST-segment elevation and in an appropriate clinical setting (chest discomfort or anginal equivalent) - Hospital admission for acute decompensated heart failure in the prior 30 days - Non-Medtronic implanted device or Medtronic device lacking Sleep Function, or Medtronic pacemaker without ICD - High pacing burden defined as >5% right ventricular pacing in the preceding month based on interrogation - Meets indication for CRT-D upgrade at the time of enrollment - Not currently on guideline-directed therapy or non-compliant with medical therapy, assessed through patient interview and review of medical charts - Non-compliant with medical visits defined as >3 missed clinical visits in the prior year - NYHA Class IV symptoms at time of enrollment - Hemodynamically significant arrhythmias including supraventricular tachycardias not responsive to rate control therapies or resulting in hemodynamic instability, sustained ventricular tachycardia (defined as >30 seconds of VT), or defibrillator shock within 4 weeks - Cardiac arrest within the prior 6 months - Coronary artery bypass graft (CABG) or percutaneous coronary intervention (PCI) within the prior 3 months, or recent coronary angiogram with plans for CABG or PCI (unrevascularized disease) - Presence of durable mechanical hemodynamic support (left ventricular assist device) - Actively listed for cardiac transplantation, prior history of cardiac transplantation or undergoing evaluation for cardiac transplantation - Actively listed for any other organ transplantation or undergoing evaluation for any other organ transplantation - Planned surgical intervention in the next 1 year - History of persistent, permanent, or long-standing atrial fibrillation - Terminal illness (other than HF) with expected survival of less than 1 year - Other end-organ, permanent dysfunction including severe chronic obstructive pulmonary disease (COPD) by Gold's criteria or severe pulmonary disease requiring oxygen, cirrhosis of any cause, renal failure on dialysis, chronic untreatable infectious disease, underlying malignancy undergoing active treatment (chemotherapy, radiation therapy, planned surgical resection of tumor), uncontrolled endocrinologic disorder (thyroid dysfunction, adrenal disease, etc.) requiring ongoing medication titration - Previous symptomatic intolerance to right ventricular pacing - Enrollment or planned enrollment in another randomized clinical trial - Inability to comply with planned study procedures - Pregnancy or nursing mothers, or women planning on becoming pregnant - Irreversible neurologic function with inability to provide own consent - Prisoners |
Country | Name | City | State |
---|---|---|---|
United States | Johns Hopkins Hospital | Baltimore | Maryland |
Lead Sponsor | Collaborator |
---|---|
Johns Hopkins University | Medtronic |
United States,
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* Note: There are 18 references in all — Click here to view all references
Type | Measure | Description | Time frame | Safety issue |
---|---|---|---|---|
Other | Change in left ventricular (LV) chamber dimensions | Change in LV chamber dimensions (systolic and diastolic dimension in centimeters) as measured via the parasternal long-axis view as part of standard echocardiography at Week 0 and Week 8. Diastolic dimensions less than 6 cm and systolic dimensions less than 4 cm are considered normal. | Baseline, Week 8 | |
Other | Change in left ventricular (LV) ejection fraction | Changes in LV ejection fraction (as a percentage) measured via method of discs via the 4-chamber apical echocardiogram view and the 2-chamber echocardiogram view at Week 0 and Week 8. Ejection fractions of 52-65% are considered normal. | Baseline, Week 8 | |
Primary | Feasibility as assessed by percent ventricular capture through Holter monitoring | Patients will be given 48-hour Holter monitors at Week 1, Week 4, and Week 7. The average heart rate in beats per minute (bpm) during sleep hours (midnight-6 AM) will be recorded. Percent ventricular capture will be defined as the percentage of heart rate during this time period that is above the pre-specified heart rate set for each patient during the "sleep" period. Percent will be defined from 0-100%, with the latter indicating all ventricular beats are paced from the right ventricle, and the former indicating that no ventricular beats are paced. | Up to 7 weeks | |
Primary | Safety as assessed by number of arrhythmia episodes via device interrogation | Patients will have patient's ICD devices interrogated throughout the study as per the study protocol, and the number of sustained ventricular tachycardia (VT) episodes, non-sustained VT episodes, and ventricular fibrillation (VF) episodes will be counted and recorded. At the conclusion of each interrogation, the device counter will be reset such that the next interrogation is only reflective of the interim time period. | Up to 3 months | |
Primary | Safety as assessed by the number of hospitalizations or ER visits for arrhythmia or heart failure | As per the study protocol, patient interviews and chart reviews will be implemented to count the number of ER visits or hospitalizations for issues related to arrhythmia or clinical heart failure decompensation. | Up to 3 months | |
Primary | Tolerability as assessed by change in Kansas City Cardiomyopathy Questionnaire (KCCQ) score | Patients will fill out the Kansas City Cardiomyopathy Questionnaire at Weeks 0, 4, 8, and 12, and a numerical score is provided at each timepoint and compared. Scores are from 0-100, with higher scores corresponding to improved quality of life and associated with New York Heart Association Class I symptoms, and lower scores associated with poorer quality of life and association with New York Heart Association Class IV symptoms. | Baseline, Week 4, Week 8 and Week 12 | |
Primary | Tolerability as assessed by change in distance during 6-minute walk test | Distance (feet) during 6 minute-walk test will be obtained and recorded at Weeks 0 and 8. Larger distances are associated with improved functional status/capacity. Typical distances covered in healthy individuals range from 1300-2300 ft. | Baseline and Week 8 | |
Primary | Safety as assessed by number of tachytherapies delivered by ICDs | Patients will have patient's ICD devices interrogated throughout the study as per the study protocol, and the number of tachytherapies delivered (ATP or ICD shocks) will be counted and recorded. At the conclusion of each interrogation, the device counter will be reset such that the next interrogation is only reflective of the interim time period. | Up to 3 months | |
Primary | Tolerability as assessed by change in Global Well-Being score on a Visual Analog Scale | Patients will fill out the Global Well-Being score at Weeks 0, 4, 8, and 12, and a numerical score is provided at each timepoint and compared. The scale is from 0-100, with higher numbers corresponding to improved well-being, and lower numbers corresponding to lower well-being. | Baseline, Week 4, Week 8 and Week 12 | |
Primary | Tolerability as assessed by change in Subjective Dyspnea score on a Visual Analog Scale | Patients will fill out the Subjective Dyspnea score at Weeks 0, 4, 8, and 12, and a numerical score is provided at each timepoint and compared. The score is from 0-100, with higher scores indicating improved subjective dyspnea, and lower scores indicating worsened subjective dyspnea. | Baseline, Week 4, Week 8 and Week 12 | |
Primary | Tolerability as assessed by change in Frailty Index | The Frailty Index will be assessed by the Johns Hopkins Older Americans Independence Center Online Frailty Assessment Tool. Patients will by assessed by the Frailty Index at Weeks 0, 4, 8, and 12, and a numerical score is provided at each timepoint and compared. The score is from 0-5, indicating frail (score 3-5), pre-frail (score 1 or 2) or robust (score 0). | Baseline, Week 4, Week 8 and Week 12 | |
Primary | Tolerability as assessed by change in Sleep Quality | Sleep Quality will be assessed by Pittsburgh Sleep Quality Index (PSQI). Patients will fill out the Pittsburgh Sleep Quality Index at Weeks 0, 1, 4, 5, 8, and 12, and a numerical score is provided at each timepoint and compared. Scores range from 0-21, with lower scores corresponding to healthier sleep habits and improved sleep quality, and higher scores corresponding to worsened sleep quality. | Baseline, Week 1, Week 4, Week 5, Week 8 and Week 12 | |
Secondary | Presence of dyssynchrony on echocardiography | Dyssynchrony will be determined by differences in right and left ventricle contraction and regional wall contraction differences in the left ventricle using echocardiography. It will be reported as present or not per participant.
Echocardiograms will be obtained at Weeks 0 and 8. To assess interventricular dyssynchrony, onset of QRS complex to peak pulmonic valve inflow or peak aortic valve inflow >40 ms or aortic pre-ejection delay >140 ms is considered significant. To assess intraventricular or LV mechanical dyssynchrony, M-mode in the parasternal long axis will be used to assess septal to posterior wall motion delay, with values >130 ms considered significant. Furthermore, time to onset or time to peak systolic velocity of 4 opposing walls >65 ms is considered significant, and will be obtained from parasternal short axis views of the LV via tissue doppler. |
Baseline, Week 8 | |
Secondary | Change in N-terminal pro b-type natriuretic peptide (NT pro-BNP) values | NT pro-BNP values (pg/mL) will be obtained at Weeks 0, 4, and 12 and be compared. Values less than 125 pg/mL are considered normal. | Baseline, Week 4 and Week 12 | |
Secondary | Change in troponin values (ng/mL) | Troponin values (ng/mL) will be obtained at Weeks 0, 4, and 12 and be compared. Values less than 0.04 ng/mL are considered normal. | Baseline, Week 4 and Week 12 | |
Secondary | Change in sodium values (mEq/L) | Changes in sodium volume (mEq/L) will be obtained at Weeks 0, 4, and 12 and be compared. Values 135-145 mEq/L are considered normal. | Baseline, Week 4 and Week 12 | |
Secondary | Change in serum creatinine values (mg/dL) | Serum creatinine values (mg/dL) will be obtained at Weeks 0, 4, and 12 and be compared. Values less than 1.2 mg/dL are considered normal. | Baseline, Week 4 and Week 12 | |
Secondary | Change in serum blood urea nitrogen (BUN) values | Serum BUN values (mg/dL) will be obtained at Weeks 0, 4, and 12 and be compared. Values 7 to 20 mg/dL are considered normal. | Baseline, Week 4 and Week 12 |
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