The goal of this clinical trial is to find out whether treating vulnerable plaques in the coronary arteries with a drug-coated balloon can make them less dangerous than using standard medication alone. The study includes adults with acute coronary syndrome (a type of heart problem caused by reduced blood flow in the coronary arteries). The main questions the study aims to answer are: * Does the drug-coated balloon reduce the amount of fat inside the plaque more than medication alone? * Is this treatment safe for patients? Participants will: * Undergo imaging of their coronary arteries during their planned heart procedure (PCI) * Be randomly assigned to receive either a drug-coated balloon treatment or no extra treatment * Undergo a heart scan (CT scan of the coronary arteries) within 2 weeks and again around 9 months after the procedure. * Undergo a second heart catherization 9 months later to examine changes in the plaque.
Rationale: Acute coronary syndromes (ACS) are often caused by rupture or erosion of certain high-risk vulnerable plaques. These plaques demonstrate specific features, such as a large lipid-rich necrotic core, a thin fibrous cap, and inflammation. Half of patients presenting with non-ST-segment elevation ACS have an additional vulnerable plaque, which increases their risk for non-culprit events during follow-up. Coronary intravascular ultrasound (IVUS) with the addition of near-infrared spectroscopy (NIRS) enables the identification of coronary lesions with high lipid content, quantified using the lipid-core burden index (LCBI) and is therefore able to distinguish plaques at risk to cause future non-culprit events. In addition, computed tomography coronary angiography (CCTA) is a non-invasive imaging modality that can identify high-risk plaque characteristics such as positive remodeling, low attentuation plaque, napkin-ring sign, and spotty calcification. Incorporating CCTA into this trial offers a unique opportunity to explore the potential of AI-based quantitative CT (AI-QCT) paramters by comparing them to IVUS-NIRS findings and clinical outcomes, which may support the future role of CCTA as a non-invasive tool for identifying and monitoring vulnerable plaques. The main question remains whether local and systemic treatment of such high-risk plaques decreases the risk for adverse clinical outcome. In our previous pilot study, DEBuT-LRP, we demonstrated that it was safe and feasible to treat vulnerable lipid-rich plaques with a drug-coated balloon (DCB) and that it was able to reduce the maximum LCBI on a 4 mm segment (maxLCBI4mm) after 9 months. In this randomized controlled trial, we intend to investigate the impact of DCB treatment on the maxLCBI4mm of lipid-rich plaques when compared to guideline-directed medical therapy alone. Objective: To test the hypothesis that paclitaxel-coated balloon treatment of non-obstructive non-culprit vulnerable lipid-rich plaques (LRP) leads to a greater reduction of the lipid-core burden index than guideline-directed medical therapy alone. Study design: A prospective two-arm randomized controlled trial. Study population: Patients older than 18 years with ACS who are scheduled for invasive percutaneous coronary intervention (PCI) of a native coronary artery. Intervention: DCB treatment of LRP in addition to guideline-directed medical therapy (GDMT). Main study parameters: The main study endpoint is the difference in maxLCBI4mm reduction from baseline to 9 months follow-up compared between the two randomization groups. Secondary study endpoints are clinical safety endpoints (1. Flow-limiting dissection related to DCB-treatment necessitating bail-out stenting; 2. Periprocedural myocardial infarction; 3. Bleeding; 4. LRP lesion failure: cardiovascular death, myocardial infarction or repeat revascularization related to the index LRP, 5. Patient-oriented outcome: all-cause death, myocardial infarction or repeat revascularization) and imaging endpoints (1. IVUS-derived parameters; 2. QCA endpoints; 3. NIRS analyses of non-treated vessels; 4. CCTA-derived parameters).
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
400
Participants in the intervention group will receive local treatment of non-obstructive, lipid-rich coronary plaques using a paclitaxel-coated drug-eluting balloon (DCB) in addition to guideline-directed medical therapy (GDMT). The DCB will be applied to plaques identified as high-risk based on near-infrared spectroscopy intravascular ultrasound (NIRS-IVUS) imaging, defined by a maxLCBI4mm ≥325. The balloon catheter diameter will be sized 1:1 according to the true lumen diameter as derived from IVUS. Balloon length will be sized to the LRP length as measured with IVUS including a 5 mm margin on each side. The balloon will be inflated at nominal pressure (6-8 ATM) during a period of at least 60 seconds, but preferably for 90 seconds if tolerated. A 5 mm margin is taken into account to differentiate between single or multiple LRPs within the same coronary artery.
Amsterdam UMC
Amsterdam, Netherlands
RECRUITINGDifference in maxLCBI4mm of the target LRP
The mean difference in maxLCBI4mm of the target LRP between baseline and 9 month follow-up compared between the two randomization groups.
Time frame: From baseline to 9 month follow-up.
Difference in maxLCBI4mm in non-treated LRPs
The change in maxLCBI4mm as measured with IVUS/NIRS from baseline to 9 month follow-up in identified additional LRPs that are not treated with DCB.
Time frame: From baseline to 9 month follow-up.
The change in IVUS- and angiography-derived measurements
The change in IVUS- and angiography-derived measurements (plaque burden, minimal lumen area, mean plaque area, diameter stenosis and minimal lumen diameter) between baseline and 9 month follow-up.
Time frame: From baseline to 9 month follow-up.
The change in CCTA-derived measurements
The change in CCTA-derived measurements using AI-QCT (total plaque volume, noncalcified plaque volume, calcified plaque volume, lumen volume and presence of the following high-risk plaque features: positive remodeling \[remodeling index \>1.1\] and low-density plaque).
Time frame: From baseline to 9 month follow-up.
Flow-limiting dissection necessitating bail-out stent implantation
Flow-limiting dissection necessitating bail-out stent implantation.
Time frame: From baseline to 9 month follow-up.
Periprocedural myocardial infarction
Procedure-related myocardial infarction is defined according to the Fourth Universal Definition for Myocardial Infarction. Periprocedural myocardial infarction has occurred when an elevation of cTn values \> 5 times of the 99th percentile URL in patients with normal baseline values is measured within a time window up to 48 hours post-procedure. Patients with elevated pre-procedural cTn values, in whom the pre-procedural cTn level are stable (≤ 20% variation) or falling, must meet the criteria for a \>5 or \>10 fold increase and manifest a change from the baseline value of \>20%. In addition with at least one of the following: * New ischaemic ECG changes; * Development of new pathological Q waves; * Imaging evidence of loss of viable myocardium that is presumed to be new and in a pattern consistent with an ischaemic aetiology; * Angiographic findings consistent with a procedural flow-limiting complication.
Time frame: From baseline to 9 month follow-up.
Bleeding (BARC-3 and -5)
The occurence of BARC Type 3 or 5 bleeding events.
Time frame: From baseline to 5 year follow-up.
LRP lesion failure
LRP lesion failure, defined as the occurence of cardiovascular death, myocardial infarction, or ischemia-driven revascularization related to an identified non-culprit LRP lesion.
Time frame: From baseline to 5 year follow-up.
Patient-oriented composite outcome
Patient-oriented composite outcome, defined as the occurrence of all-cause mortality, myocardial infarction, or any repeat revascularization.
Time frame: From baseline to 5 year follow-up.
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