Study to Assess Safety and Efficacy of Treating Symptomatic, Ischemic, Chronic Congestive Heart Failure Patients with an LVEF of ≤40% with Fresh, Uncultured, Autologous, Adipose-derived Regenerative Cells Isolated from Lipoaspirate.
NCT ID: NCT06705023
Last Updated: 2024-12-03
Study Results
Results pending
The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.
Basic Information
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Recruitment Status
RECRUITING
Clinical Phase
PHASE2
Total Enrollment
36 participants
Study Classification
INTERVENTIONAL
Study Start Date
2024-11-18
Study Completion Date
2025-12-31
Brief Summary
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To investigate patients suffering from iHF and a LVEF of equal or less than 40% despite best medical treatment safety and efficacy of a single retrograde intra-cardiac venous (i.cv.) injection of UA-ADRCs isolated from lipoaspirate at the point of care, using the Transpose® RT / Matrase System (InGeneron, Houston, TX, USA) through an over-the- wire, small balloon catheter, advanced through the coronary si-nus and located within a coronary vein at the site of inter-est, versus patients on best medical treatment.
Detailed Description
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The aim of the study is to investigate patients suffering from chronic congestive heart failure (iHF) and a left ventricular ejection fraction (LVEF) of equal or less than 40% despite best medical treatment safety and efficacy of a single retrograde intra-cardiac venous (i.cv.) injection of uncultured, autologous, adipose-derived regenerative cells (UA-ADRCs) isolated from lipoaspirate at the point of care. The cells will be isolated using the Transpose® RT / Matrase System (InGeneron, Houston, TX, USA) through an over-the-wire, small balloon catheter, advanced through the coronary sinus and located within a coronary vein at the site of interest, versus patients on best medical treatment.
This study hypothesizes that treatment of iHF with a balloon-enhanced i.cv. injection of UA-ADRCs isolated from lipoaspirate at the point of care using the Transpose RT / Matrase system (InGeneron) is safe and effective and is more effective than best medical treatment.
The primary objective of this study is to evaluate safety and efficacy of treating iHF with a single, balloon-enhanced retrograde i.cv. injection of UA-ADRCs. Efficacy will be demonstrated in a superiority study design by comparing improvement in global cardiac functional parameters demonstrated using cardiac magnetic resonance imaging (cMRI) or Cardiac CT, and by clinical endpoints after a single i.cv. injection of UA-ADRCs, to best medical treatment. Safety will be demonstrated by reporting major ad-verse cardiac events (MACE) and other adverse events.
A total of n=36 patients with iHF and a reduced LVEF (at ≤40%) will be randomly assigned to i.cv. injection of either UA-ADRCs (UA-ADRCs Group; n=24) or best medical treatment (Control Group; n=12). The enrollment will take place up to four study sites, among them the National Science Research Center of the Principal Investigator (Dr. Abay Baigenzhin) in Astana (Kazakhstan), will enroll 36 patients in the study. The study duration is the time to enroll patients in the study and will take 6 months. Individual follow-up time after the treatment is 6 months.
Follow-up schedule is as follows. Follow-up visits will take place at 1, 3, and 6 months post- treatment. Follow-up visit will include an assessment by cMRI, or cCT, physical examinations including echocardiography, patient-reported outcome questionnaires, control of medication usage, number of hospitalizations for cardiac conditions, and adverse event monitoring (including MACE). Those patients in the control group that have finished the 1, 3, and 6 month follow up visits will be offered to be treated with stem cell therapy as well. All remaining patients in both groups will be offered to participate in a subsequent registry study for 12 and 24-month follow-up vis-its, that could include physical examinations, patient-reported outcome questionnaires, medication usage, number of hospitalizations for cardiac conditions, and adverse event monitoring (including MACE) and cMRI or cCT. These long-term data would be compared to the corresponding baseline data.
The Primary Endpoint is to be cardiac function represented by left ventricular ejection fraction (LVEF) at 6 months assessed by cardiac MRI (cMRI) or cCT. Treatment success is defined as a 15% relative increase of LVEF from baseline to 6-month follow-up. Treatment success is expected in 65% of patients in the treatment group vs 10% in the control group. Secondary Endpoints will be assessed at baseline and at 6 months post-treatment and will include:
1. n-terminal pro-b-type natriuretic peptide (NT-proBNP),
2. 6-min walk test,
3. the Minnesota Living with Heart Failure Ques-tionnaire (MLHFQ) score,
4. need for hospitalization due to cardiac conditions, cardiac related death,
5. incidence of treatment-related adverse events (in-cluding MACE),
6. Only in patients with cMRI: relative amount of left ven-tricular scar tissue, left ventricular bull's eye segmental contracting areas.
This is a prospective, randomized, controlled, multicenter, safety and efficacy study in patients with iHF comparing best available medical treatment plus a balloon-enhanced single i.cv. injection of UA-ADRCs isolated from lipoaspirate at point of care using the Transpose RT / Matrase system (InGeneron) in 24 patients, to best available medical treatment in 12 patients in the control group.
Background Heart failure and myocardial infarction (MI) are consequences of ischemic heart disease (IHD) \[1\]. In recent years cell-based therapies have emerged as a promising strategy to re-generate ischemic myocardium \[2-4\]. However, the generally disappointing outcome of related clinical trials established a need for developing novel, more effective cell-based therapies for MI. In this regard, it is of note that the treatment of chronic MI (i.e., patients with a previous MI) (CMI) requires a different approach than the treatment of acute MI (AMI).
The amount of pluripotent stem cells has been reported to be significantly higher in adipose tissue than in bone marrow (5% to 10% vs. 0.1%) \[12\]. Fresh, uncultured, unmodified, autologous adipose-derived regenerative cells (UA-ADRCs) have the advantage over culture-expanded adipose-derived stem cells (ASCs) that UA-ADRCs allow for immediate usage at the point of care, combined with low safety concerns, since no culturing or modification is applied.
Several experimental studies in animal models have demonstrated the potential of UA-ADRCs for treating AMI \[13-15\], and a first clinical trial (APOLLO) showed promising preliminary results \[16\]. The investigators recently published results of a preclinical porcine study regarding the treatment of chronic ischemic heart failure (\> 4 wk post-MI) with UA-ADRCs \[28\]. This study demonstrated that retrograde delivery of UA-ADRCs in a porcine model of chronic ischemic heart failure significantly improved myocardial function, increased myocardial mass, and reduced scar tissue formation. As part of this study, an evidence-based systematic review of the literature according to the PRISMA guidelines was conducted to examine preclinical studies on the treatment of iHF with stem cells \[28\].
Preliminary results from a study including 28 patients with chronic ischemic cardiomyopathy In one study evaluating the safety and preliminary efficacy of stromal vascular fraction ad-ministration (by a needle catheter into the myocardium) including 28 patients with chronic ischemic cardiomyopathy, the authors reported results from the six-minute walk test and LVEF at baseline and three and six months (with additional testing at 12 months if applicable) after treatment. LVEF increased from baseline to three and six months of follow-up. Results from a six-minute walk test showed a performance increase of about 80m from baseline to three, six, and twelve months of follow-up \[18\].
Results of our initial open-label Pilot Study in patients with inclusion and exclusion criteria comparable to the now designed randomized prospective study The pilot phase study for this randomized study was conducted in collaboration with the National Scientific Medical Center, Astana, Kazakhstan. Six patients were enrolled (five male, one female, NYHA class III, age 61.3±6.2 years) with the diagnosis of chronic ischemic heart failure and no improvement of symptoms or function after standard therapy for at least one month. All patients had documented coronary artery disease with evidence of myocardial injury and left ventricular dysfunction. Five out of six participants presented LVEF of ≤40%. All patients underwent liposuction under conscious sedation and local anesthesia. Lipoaspirate was processed according to the established InGeneron procedure to produce a cellular suspension of stromal vascular fraction including UA-ADRCs using the Transpose® RT / Matrase System (InGeneron, Houston, TX, USA). This cellular preparation was retrogradely injected via the coronary sinus into the corresponding coronary vein. The main outcome of interest was the change of LVEF (assessed by cMRI) from baseline to 3-6 months. In five of the six patients, an improvement in LVEF was observed. Further, adverse events reported were related to mild bruising/swelling/redness at the site of the liposuction in the abdominal area. There were no hospitalizations or health decline due to HF symptoms throughout the initial follow-up phase.
Rationale and Outcomes for Using UA-ADRCs
UA-ADRCs have several advantages over other types of cells used in and/or under investigation for regenerative cell therapy:
* UA-ADRCs do not share ethical concerns nor the risk of teratoma formation as reported for embryonic stem cells \[19-21\].
* Neither UA-ADRCs share the risk of tumorigenesis \[22-24\].
* Because UA-ADRCs are autologous cells which does not bear the risk of HLA mismatch \[25-27\].
* Adipose tissue is relatively easy to be harvested in most patients through liposuction. Furthermore, uncultured vascular-associated MSCs can represent up to 12% of the total population of SVF cells \[28\], whereas only 0.001%-0.1% of the total population of bone marrow nucleated cells are considered true stem cells \[31, 32\].
* Harvesting adipose tissue by liposuction is typically less invasive than harvesting bone marrow \[31, 33, 34\] with mini liposuction required.
* The use of fresh UA-ADRCs allows immediate usage at point of care \[14, 41-43\].
* When using UA-ADRCs during the same surgical procedure in an autologous and homologous way, they have not been considered as advanced therapy medicinal product (ATMP) by the European Medicines Agency \[40\].
* Recent studies indicated non-inferiority or even superiority of UA-ADRCs over ASCs in, for example, rescuing heart function after acute myocardial infarction \[48\], bone regeneration \[50\], and tendon regeneration \[51\] (see also \[4\]).
An optimal system for providing UA-ADRCs at the point of care should be capable of isolating the highest possible number of living ADRCs from the lowest possible amount of adipose tissue, in the shortest possible time, and providing the cells at the highest possible concentration in a final cell suspension. In this regard, it has been demonstrated in the literature that the Transpose RT / Matrase sys-tem (InGeneron, Houston, TX, USA) is the most efficient method with respect to the viable cell yield (i.e., the number of living cells / mL lipoaspirate).
Specifically, the investigators hypothesize that (i) a single i.cv injection of UA-ADRCs isolated with the Transpose RT / Matrase system (InGeneron) is safe and effective in the treatment of iHF, (ii) this therapy is statistically significantly more effective than just guideline based drug treatment, and (iii) i.cv injection of UA-ADRCs will possibly gain widespread acceptance, if safety and higher effectiveness than standard maximum drug therapy will be demonstrated by this and following multicenter randomized controlled trials.
This study hypothesizes that treatment of iHF with a balloon-enhanced i.cv. injection of UA-ADRCs isolated from lipoaspirate at the point of care using the Transpose RT / Matrase system (InGeneron) is safe and effective and is more effective than best medical treatment.
The primary objective of this study is to evaluate safety and efficacy of treating iHF with a single, balloon-enhanced retrograde i.cv. injection of UA-ADRCs. Efficacy will be demonstrated in a superiority study design by comparing improvement in global cardiac functional parameters demonstrated using cardiac magnetic resonance imaging (cMRI) or Cardiac CT, and by clinical endpoints after a single i.cv. injection of UA-ADRCs, to best medical treatment. Safety will be demonstrated by reporting major ad-verse cardiac events (MACE) and other adverse events.
A total of n=36 patients with iHF and a reduced LVEF (at ≤40%) will be randomly assigned to i.cv. injection of either UA-ADRCs (UA-ADRCs Group; n=24) or best medical treatment (Control Group; n=12). The enrollment will take place up to four study sites, among them the National Science Research Center of the Principal Investigator (Dr. Abay Baigenzhin) in Astana (Kazakhstan), will enroll 36 patients in the study. The study duration is the time to enroll patients in the study and will take 6 months. Individual follow-up time after the treatment is 6 months.
Follow-up schedule is as follows. Follow-up visits will take place at 1, 3, and 6 months post- treatment. Follow-up visit will include an assessment by cMRI, or cCT, physical examinations including echocardiography, patient-reported outcome questionnaires, control of medication usage, number of hospitalizations for cardiac conditions, and adverse event monitoring (including MACE). Those patients in the control group that have finished the 1, 3, and 6 month follow up visits will be offered to be treated with stem cell therapy as well. All remaining patients in both groups will be offered to participate in a subsequent registry study for 12 and 24-month follow-up vis-its, that could include physical examinations, patient-reported outcome questionnaires, medication usage, number of hospitalizations for cardiac conditions, and adverse event monitoring (including MACE) and cMRI or cCT. These long-term data would be compared to the corresponding baseline data.
The Primary Endpoint is to be cardiac function represented by left ventricular ejection fraction (LVEF) at 6 months assessed by cardiac MRI (cMRI) or cCT. Treatment success is defined as a 15% relative increase of LVEF from baseline to 6-month follow-up. Treatment success is expected in 65% of patients in the treatment group vs 10% in the control group. Secondary Endpoints will be assessed at baseline and at 6 months post-treatment and will include:
1. n-terminal pro-b-type natriuretic peptide (NT-proBNP),
2. 6-min walk test,
3. the Minnesota Living with Heart Failure Ques-tionnaire (MLHFQ) score,
4. need for hospitalization due to cardiac conditions, cardiac related death,
5. incidence of treatment-related adverse events (in-cluding MACE),
6. Only in patients with cMRI: relative amount of left ven-tricular scar tissue, left ventricular bull's eye segmental contracting areas.
This is a prospective, randomized, controlled, multicenter, safety and efficacy study in patients with iHF comparing best available medical treatment plus a balloon-enhanced single i.cv. injection of UA-ADRCs isolated from lipoaspirate at point of care using the Transpose RT / Matrase system (InGeneron) in 24 patients, to best available medical treatment in 12 patients in the control group.
Background Heart failure and myocardial infarction (MI) are consequences of ischemic heart disease (IHD) \[1\]. In recent years cell-based therapies have emerged as a promising strategy to re-generate ischemic myocardium \[2-4\]. However, the generally disappointing outcome of related clinical trials established a need for developing novel, more effective cell-based therapies for MI. In this regard, it is of note that the treatment of chronic MI (i.e., patients with a previous MI) (CMI) requires a different approach than the treatment of acute MI (AMI).
The amount of pluripotent stem cells has been reported to be significantly higher in adipose tissue than in bone marrow (5% to 10% vs. 0.1%) \[12\]. Fresh, uncultured, unmodified, autologous adipose-derived regenerative cells (UA-ADRCs) have the advantage over culture-expanded adipose-derived stem cells (ASCs) that UA-ADRCs allow for immediate usage at the point of care, combined with low safety concerns, since no culturing or modification is applied.
Several experimental studies in animal models have demonstrated the potential of UA-ADRCs for treating AMI \[13-15\], and a first clinical trial (APOLLO) showed promising preliminary results \[16\]. The investigators recently published results of a preclinical porcine study regarding the treatment of chronic ischemic heart failure (\> 4 wk post-MI) with UA-ADRCs \[28\]. This study demonstrated that retrograde delivery of UA-ADRCs in a porcine model of chronic ischemic heart failure significantly improved myocardial function, increased myocardial mass, and reduced scar tissue formation. As part of this study, an evidence-based systematic review of the literature according to the PRISMA guidelines was conducted to examine preclinical studies on the treatment of iHF with stem cells \[28\].
Preliminary results from a study including 28 patients with chronic ischemic cardiomyopathy In one study evaluating the safety and preliminary efficacy of stromal vascular fraction ad-ministration (by a needle catheter into the myocardium) including 28 patients with chronic ischemic cardiomyopathy, the authors reported results from the six-minute walk test and LVEF at baseline and three and six months (with additional testing at 12 months if applicable) after treatment. LVEF increased from baseline to three and six months of follow-up. Results from a six-minute walk test showed a performance increase of about 80m from baseline to three, six, and twelve months of follow-up \[18\].
Results of our initial open-label Pilot Study in patients with inclusion and exclusion criteria comparable to the now designed randomized prospective study The pilot phase study for this randomized study was conducted in collaboration with the National Scientific Medical Center, Astana, Kazakhstan. Six patients were enrolled (five male, one female, NYHA class III, age 61.3±6.2 years) with the diagnosis of chronic ischemic heart failure and no improvement of symptoms or function after standard therapy for at least one month. All patients had documented coronary artery disease with evidence of myocardial injury and left ventricular dysfunction. Five out of six participants presented LVEF of ≤40%. All patients underwent liposuction under conscious sedation and local anesthesia. Lipoaspirate was processed according to the established InGeneron procedure to produce a cellular suspension of stromal vascular fraction including UA-ADRCs using the Transpose® RT / Matrase System (InGeneron, Houston, TX, USA). This cellular preparation was retrogradely injected via the coronary sinus into the corresponding coronary vein. The main outcome of interest was the change of LVEF (assessed by cMRI) from baseline to 3-6 months. In five of the six patients, an improvement in LVEF was observed. Further, adverse events reported were related to mild bruising/swelling/redness at the site of the liposuction in the abdominal area. There were no hospitalizations or health decline due to HF symptoms throughout the initial follow-up phase.
Rationale and Outcomes for Using UA-ADRCs
UA-ADRCs have several advantages over other types of cells used in and/or under investigation for regenerative cell therapy:
* UA-ADRCs do not share ethical concerns nor the risk of teratoma formation as reported for embryonic stem cells \[19-21\].
* Neither UA-ADRCs share the risk of tumorigenesis \[22-24\].
* Because UA-ADRCs are autologous cells which does not bear the risk of HLA mismatch \[25-27\].
* Adipose tissue is relatively easy to be harvested in most patients through liposuction. Furthermore, uncultured vascular-associated MSCs can represent up to 12% of the total population of SVF cells \[28\], whereas only 0.001%-0.1% of the total population of bone marrow nucleated cells are considered true stem cells \[31, 32\].
* Harvesting adipose tissue by liposuction is typically less invasive than harvesting bone marrow \[31, 33, 34\] with mini liposuction required.
* The use of fresh UA-ADRCs allows immediate usage at point of care \[14, 41-43\].
* When using UA-ADRCs during the same surgical procedure in an autologous and homologous way, they have not been considered as advanced therapy medicinal product (ATMP) by the European Medicines Agency \[40\].
* Recent studies indicated non-inferiority or even superiority of UA-ADRCs over ASCs in, for example, rescuing heart function after acute myocardial infarction \[48\], bone regeneration \[50\], and tendon regeneration \[51\] (see also \[4\]).
An optimal system for providing UA-ADRCs at the point of care should be capable of isolating the highest possible number of living ADRCs from the lowest possible amount of adipose tissue, in the shortest possible time, and providing the cells at the highest possible concentration in a final cell suspension. In this regard, it has been demonstrated in the literature that the Transpose RT / Matrase sys-tem (InGeneron, Houston, TX, USA) is the most efficient method with respect to the viable cell yield (i.e., the number of living cells / mL lipoaspirate).
Specifically, the investigators hypothesize that (i) a single i.cv injection of UA-ADRCs isolated with the Transpose RT / Matrase system (InGeneron) is safe and effective in the treatment of iHF, (ii) this therapy is statistically significantly more effective than just guideline based drug treatment, and (iii) i.cv injection of UA-ADRCs will possibly gain widespread acceptance, if safety and higher effectiveness than standard maximum drug therapy will be demonstrated by this and following multicenter randomized controlled trials.
Conditions
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Myocardial Injury
LV Dysfunction
Coronary Artery Disease
Heart Failure
Study Design
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Allocation Method
RANDOMIZED
Intervention Model
PARALLEL
This is a prospective, randomized, controlled, multicenter, safety and efficacy study in patients with iHF comparing best available medical treatment plus a balloon-enhanced single i.cv. injection of UA-ADRCs isolated from lipoaspirate at point of care using the Transpose RT / Matrase system (InGeneron) in 24 patients, to best available medical treatment in 12 patients in the control group
Primary Study Purpose
TREATMENT
Blinding Strategy
SINGLE
Outcome Assessors
Study Groups
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UA-ADRCs group
Patients in the UA-ADRC (uncultured, autologous, adipose-derived regenerative cells) group will be treated as follows:
1. Patients will have an outpatient liposuction procedure from the abdomen, bilateral flanks, and/or medial thigh (at least 100 mL of adipose tissue) to get cell product.
2. Oral sedation and local anesthesia with tumescent solution will be used. Patients' vitals will be monitored and recorded during the procedure and in 1 to 2 hours post-procedure.
3. Each patient in the UA-ADRC group will have cells isolated using the Transpose RT/Matrase system (InGeneron).
4. Cell product testing will be assessed with the following acceptance criteria: total nucleated cell count is \> 35 million cells, b) cell viability is \> 75%. AE status will be monitored for 30 days post-liposuction procedure.
5. The i.cv injection of UA-ADRCs will be given using an aseptic technique. This group will include 24 patients.
Group Type
EXPERIMENTAL
Uncultured, autologous, adipose-derived regenerative cells (UA-ADRCs)
Intervention Type
BIOLOGICAL
Intracardial venous injection of fresh, uncultured, autologous, adipose-derived regenerative cells isolated from lipoaspirate at the point of care.
Control group
Patients will receive continuation of their best guideline based medical treatment. This group will include 12 patients.
Group Type
ACTIVE_COMPARATOR
Continuation of patient's best guideline based medical treatment
Intervention Type
OTHER
Patients will receive continuation of their best guideline based medical treatment.
Interventions
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Uncultured, autologous, adipose-derived regenerative cells (UA-ADRCs)
Intracardial venous injection of fresh, uncultured, autologous, adipose-derived regenerative cells isolated from lipoaspirate at the point of care.
Intervention Type
BIOLOGICAL
Continuation of patient's best guideline based medical treatment
Patients will receive continuation of their best guideline based medical treatment.
Intervention Type
OTHER
Eligibility Criteria
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Inclusion Criteria
* Have documented coronary artery disease with evidence of myocardial injury, LV dysfunction, and clinical evidence of heart failure
* Have an EF ≤40% by cardiac MRI
* Be receiving guideline-driven medical therapy for heart failure at stable and tolerated doses for ≥1 month before consent
* Be a candidate for right heart cardiac catheterization
* Have New York Heart Association class I, II, or III heart failure symptoms
* If a female of childbearing potential, be willing to use one form of birth control for the duration of the study, and undergo a pregnancy test at baseline and within 36 h before treatment
* Have an EF ≤40% by cardiac MRI
* Be receiving guideline-driven medical therapy for heart failure at stable and tolerated doses for ≥1 month before consent
* Be a candidate for right heart cardiac catheterization
* Have New York Heart Association class I, II, or III heart failure symptoms
* If a female of childbearing potential, be willing to use one form of birth control for the duration of the study, and undergo a pregnancy test at baseline and within 36 h before treatment
Exclusion Criteria
* Indication for standard-of-care surgery (including valve surgery, placement of LV assist device, or imminent heart transplantation), CABG procedure, and PCI. Candidates cannot be UNOS 1A or 1B, and they must have documented low probability of being transplanted.
* PCI within 3 months of randomization
* CABG within 3 months of randomization
* Valvular heart disease including mechanical or bioprosthetic heart valve, severe valvular (any valve) insufficiency/regurgitation within 12 month of consent, and aortic stenosis with valve area ≤1.5 cm2
* History of ischemic or hemorrhagic stroke within 90 d of consent
* History of an LV remodeling surgical procedure utilizing prosthetic material
* Presence of a pacemaker and ICD generator with any of the following limitations/conditions: manufactured before the year 2015
* Leads implanted \<6 week before consent
* Non-transvenous epicardial or abandoned leads
* Subcutaneous ICDs
* Leadless pacemakers
* Pacemaker-dependence with an ICD (pacemaker-dependent candidates without an ICD are not excluded)
* Any other condition that, in the judgment of device-trained staff, would deem an MRI contraindicated
* A CRT device implanted within 3 months of consent
* An appropriate ICD firing or antitachycardia pacing for ventricular fibrillation or ventricular tachycardia within 30 days of consent
* Ventricular tachycardia (≥20 consecutive beats) without an ICD within 3 month of consent, or symptomatic Mobitz II or higher degree atrioventricular block without a functioning pacemaker within 3 months of consent
* Presence of LV thrombus
* Baseline eGFR \<35 mL/min per 1.73 m2
* Poorly controlled blood glucose levels (HbA1c \>10%)
* Hematologic abnormality evidenced by hematocrit \<25%, white blood cell \<2500 per μL, or platelet count \<100 000 per μL
* Liver dysfunction evidenced by enzymes (AST and ALT) ˃ 3× the ULN
* Coagulopathy (INR ≥1.3) not due to a reversible cause (eg, warfarin and factor Xa inhibitors). Patients who cannot be withdrawn from anticoagulation will be excluded.
* HIV or active HBV or HCV
* Allergy to radiographic contrast material that cannot adequately be managed by premedication
* Known history of anaphylactic reaction to penicillin or streptomycin
* Received gene or cell-based therapy from any source within the previous 12 months
* History of malignancy within 3 years, excluding basal cell carcinoma or cervical carcinoma in situ which have been definitively treated
* Condition that limits expected lifespan to \<1 year
* History of drug or alcohol abuse
* Chronic immunosuppressant therapy such as corticosteroids or TNF-α antagonists
* Cognitive or language barriers that prohibit obtaining informed consent or any study elements
* Pregnancy or lactation or plans to become pregnant in the next 12 months
* Conditions that, in the judgment of the Investigator or Sponsor, would impair enrollment, cell harvest, administration or follow-up
ALT indicates alanine aminotransferase; AST, aspartate aminotransferase; CABG, coronary artery bypass grafting; CRT, cardiac resynchronization therapy; EF, ejection fraction; eGFR, estimated glomerular filtration rate; HBV, hepatitis B virus; HCV, hepatitis C virus; HIV, human immunodeficiency virus; ICD, implantable cardioverter defibrillator; INR, international normalized ratio; LV, left ventricular; MRI, magnetic resonance imaging; PCI, percutaneous coronary intervention; TNF-α, tumor necrosis factor-α; ULN, upper limit of normal; UNOS, United Network for Organ Sharing; and Vo2 max, maximal oxygen consumption.
* PCI within 3 months of randomization
* CABG within 3 months of randomization
* Valvular heart disease including mechanical or bioprosthetic heart valve, severe valvular (any valve) insufficiency/regurgitation within 12 month of consent, and aortic stenosis with valve area ≤1.5 cm2
* History of ischemic or hemorrhagic stroke within 90 d of consent
* History of an LV remodeling surgical procedure utilizing prosthetic material
* Presence of a pacemaker and ICD generator with any of the following limitations/conditions: manufactured before the year 2015
* Leads implanted \<6 week before consent
* Non-transvenous epicardial or abandoned leads
* Subcutaneous ICDs
* Leadless pacemakers
* Pacemaker-dependence with an ICD (pacemaker-dependent candidates without an ICD are not excluded)
* Any other condition that, in the judgment of device-trained staff, would deem an MRI contraindicated
* A CRT device implanted within 3 months of consent
* An appropriate ICD firing or antitachycardia pacing for ventricular fibrillation or ventricular tachycardia within 30 days of consent
* Ventricular tachycardia (≥20 consecutive beats) without an ICD within 3 month of consent, or symptomatic Mobitz II or higher degree atrioventricular block without a functioning pacemaker within 3 months of consent
* Presence of LV thrombus
* Baseline eGFR \<35 mL/min per 1.73 m2
* Poorly controlled blood glucose levels (HbA1c \>10%)
* Hematologic abnormality evidenced by hematocrit \<25%, white blood cell \<2500 per μL, or platelet count \<100 000 per μL
* Liver dysfunction evidenced by enzymes (AST and ALT) ˃ 3× the ULN
* Coagulopathy (INR ≥1.3) not due to a reversible cause (eg, warfarin and factor Xa inhibitors). Patients who cannot be withdrawn from anticoagulation will be excluded.
* HIV or active HBV or HCV
* Allergy to radiographic contrast material that cannot adequately be managed by premedication
* Known history of anaphylactic reaction to penicillin or streptomycin
* Received gene or cell-based therapy from any source within the previous 12 months
* History of malignancy within 3 years, excluding basal cell carcinoma or cervical carcinoma in situ which have been definitively treated
* Condition that limits expected lifespan to \<1 year
* History of drug or alcohol abuse
* Chronic immunosuppressant therapy such as corticosteroids or TNF-α antagonists
* Cognitive or language barriers that prohibit obtaining informed consent or any study elements
* Pregnancy or lactation or plans to become pregnant in the next 12 months
* Conditions that, in the judgment of the Investigator or Sponsor, would impair enrollment, cell harvest, administration or follow-up
ALT indicates alanine aminotransferase; AST, aspartate aminotransferase; CABG, coronary artery bypass grafting; CRT, cardiac resynchronization therapy; EF, ejection fraction; eGFR, estimated glomerular filtration rate; HBV, hepatitis B virus; HCV, hepatitis C virus; HIV, human immunodeficiency virus; ICD, implantable cardioverter defibrillator; INR, international normalized ratio; LV, left ventricular; MRI, magnetic resonance imaging; PCI, percutaneous coronary intervention; TNF-α, tumor necrosis factor-α; ULN, upper limit of normal; UNOS, United Network for Organ Sharing; and Vo2 max, maximal oxygen consumption.
Minimum Eligible Age
21 Years
Maximum Eligible Age
80 Years
Eligible Sex
ALL
Accepts Healthy Volunteers
No
Sponsors
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National Scientific Medical Center, Kazakhstan
OTHER_GOV
Sponsor Role
collaborator
Internationnal Foundation Medicine and Science
UNKNOWN
Sponsor Role
collaborator
Alliance of Cardiovascular Researchers
OTHER
Sponsor Role
collaborator
Ralf Rothoerl
OTHER
Sponsor Role
lead
Responsible Party
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Ralf Rothoerl
coordinator
Responsibility Role
SPONSOR_INVESTIGATOR
Principal Investigators
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Abay Baigenzhin, Prof Dr
Role: PRINCIPAL_INVESTIGATOR
National Scientific Medical Center
Ralf Rothoerl, Dr
Role: STUDY_DIRECTOR
International Foundation of Medicine and Science
Locations
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National Scientific Medical Center
Astana, , Kazakhstan
Site Status
RECRUITING
Countries
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Kazakhstan
Central Contacts
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Facility Contacts
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Ralf Roethoerl, Dr
Role: backup
References
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Anderson JL, Morrow DA. Acute Myocardial Infarction. N Engl J Med. 2017 May 25;376(21):2053-2064. doi: 10.1056/NEJMra1606915. No abstract available.
Reference Type
BACKGROUND
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Other Identifiers
Review additional registry numbers or institutional identifiers associated with this trial.
001
Identifier Type: -
Identifier Source: org_study_id