Balloon angioplasty is the inflation of a balloon (often part of an integrated medical device combining a balloon, guidewire, and stent) within the coronary artery to 'crush' the plaque causing the occlusion into the walls of the artery. Balloon angioplasty is still often performed as a part of PCI procedure, it is rarely the only activity performed. Procedures commonly associated with PCI are: • Implantation of
stents • Arterial blockage debulking: removal or reshaping of plaque • Rotational, orbital, and/or laser
atherectomy (cutting plaque out) •
Brachytherapy (use of radioactive source to inhibit
restenosis) • Coronary intravascular
lithotripsy (IVL), or using sonic waves to break up calcified plaques PCI consists of preparation of the skin area to be accessed (groin or arm), by shaving and swabbing the area with a bacteriostatic agent, usually a
chlorhexidine based product. An introducer needle is inserted into the target artery. Once the access is gained, a "sheath introducer" is inserted to keep the artery open. This procedure is termed
percutaneous access. As of 2023, catheter systems used in PCI procedures are often fully integrated medical devices. They are usually referred to as "over the wire" or OTW catheters. Typically having two lumen paths (a cavity within any tubular structure), the larger one for the navigating highly flexible guidewire and the smaller one for inflating and deflating the balloon or balloon/catheter assembly. The guidewire lumen extends the total length of the catheter. A balloon-stent is often part of the assembled device, other features may also be part of the medical device design depending on the nature of the procedure. The interventional cardiologist uses the entry point created during the percutaneous access step, to introduce the catheter system and guides it to the
occluded area of the coronary artery being treated, using
fluoroscopy and
radiopaque dyes as an imaging tool. The device and its balloon/stent components can be inflated to open the
stenotic diseased artery area. When a stent is used, the stent tube mesh is initially collapsed onto the balloon component of the catheter. In this collapsed state, it is small enough to be passed through relatively narrow peripheral arteries and then inflated by the underlying balloon and pressed firmly against the diseased coronary artery wall. It is expanded by pressure introduced by injecting physiological saline into the device through the lumen of the still attached catheter. Inflation time and pressure used are recorded during this placement procedure. After the balloon inflation/deflation or the deposition of the stent, the placement device/deflated balloon are removed leaving the stent in place. The interventional cardiologist decides how to treat the blockage in the best way during the PCI/stent placement, based on real-time data. The cardiologist uses imaging data provided by both
intravascular ultrasound (IVUS), and
fluoroscopic imaging (combined with a
radiopaque dye) during the procedure. The information obtained from these two sources enables the cardiologist to track the path of the catheter-device as it moves through the arterial vessels. This information also helps determine both the location and physical characteristics of plaque(s) causing narrowing in the arteries. Data from these two techniques is used to correctly position the stent and to obtain detailed information relating to the coronary arterial anatomy. This anatomy varies greatly among individuals, having this information becomes crucial for effective treatment. The obtained data is recorded on video and is of value in cases when future treatment is needed.
Types of stent placed by percutaneous coronary intervention. Older
bare-metal stents (BMS) provide a mechanical framework that holds the artery wall open, preventing stenosis, or narrowing, of coronary arteries. Newer
drug-eluting stents (DES) are traditional stents with a polymer coating containing drugs that prevent cell proliferation. The antiproliferative drugs are released slowly over time to help prevent tissue growth. DES stents have been shown to help prevent
restenosis of the artery through mechanisms that rely upon the suppression of tissue growth at the stent site and local modulation of the body's inflammatory and immune responses. The first two drug-eluting stents to be utilized were the
paclitaxel-eluting stent and the
sirolimus-eluting stent, both of which have received approval from the U.S. Food and Drug Administration. Most current FDA-approved drug-eluting stents use sirolimus (also known as rapamycin),
everolimus and
zotarolimus. Biolimus A9-eluting stents, which utilize biodegradable polymers, are approved outside the U.S. Newer-generation PCI technologies aim to reduce the risk of late stent thrombosis or other long-term adverse events. Some DES products market a biodegradable polymer coating with the belief that the permanent polymer coatings of DES contribute to long-term inflammation. Other strategies: A more recent study proposes that in the case of population with diabetes mellitus—a population particularly at risk—a treatment with paclitaxel-eluting balloon followed by BMS may reduce the incidence of coronary restenosis or myocardial infarction compared with BMS administered alone. After placement of a stent or scaffold, the patient needs to take two antiplatelet medications (aspirin and one of a few other options) for several months to help prevent blood clots. The length of time a patient needs to be on dual antiplatelet therapy is individualized based risks of ischemic events and bleeding risk.
Thrombus aspiration In primary PCI,
angiography may demonstrate
thrombus (blood clots) inside the coronary arteries. Various studies have been performed to determine whether aspirating these clots (thrombus aspiration or manual thrombectomy) is beneficial. At the moment there is no evidence that routine clot aspiration improves outcomes.
Complex lesions Lesions with a high degree of calcium deposition within the vessel wall, especially if the calcium is circumferential, are considered to be hard to dilate in regards to balloon
angioplasty. Complex lesions are one of the key predictors of poor outcome in percutaneous coronary intervention (PCI), hence calcium lesion modification is needed before implantations of stents. The aim is to create cracks in the calcium within the vessel wall in order to increase the likelihood of successful expansion of the stenosis and delivery of the final stent. This is traditionally achieved by balloon
angioplasty or debulking strategies including rotational, orbital and laser atherectomy. However, coronary intravascular
lithotripsy using acoustic shockwaves is a novel approach for treating superficial and deep calcium in the vessel wall. == Recovery and rehabilitation ==