Percutaneous coronary intervention

Percutaneous coronary intervention
Intervention

A coronary angiogram (an X-ray with radio-opaque contrast in the coronary arteries) that shows the left coronary circulation. The distal left main coronary artery (LMCA) is in the left upper quadrant of the image. Its main branches (also visible) are the left circumflex artery (LCX), which courses top-to-bottom initially and then toward the centre/bottom, and the left anterior descending (LAD) artery, which courses from left-to-right on the image and then courses down the middle of the image to project underneath of the distal LCX. The LAD, as is usual, has two large diagonal branches, which arise at the centre-top of the image and course toward the centre/right of the image.
ICD-9-CM 36.09, 00.66

Percutaneous coronary intervention (PCI), commonly known as coronary angioplasty or simply angioplasty, is a non-surgical procedure used to treat the stenotic (narrowed) coronary arteries of the heart found in coronary heart disease. These stenotic segments are due to the buildup of the cholesterol-laden plaques that form due to atherosclerosis. PCI is usually performed by an interventional cardiologist, though it was developed and originally performed by interventional radiologists.

During PCI, a cardiologist feeds a deflated balloon or other device on a catheter from the inguinal femoral artery or radial artery up through blood vessels until they reach the site of blockage in the heart. X-ray imaging is used to guide the catheter threading. Angioplasty usually involves inflating a balloon to open the artery and allow blood flow. Stents or scaffolds may be placed at the site of the blockage to hold the artery open.

Coronary artery bypass grafting (CABG), which bypasses stenotic arteries by grafting vessels from elsewhere in the body, is an alternative treatment to PCI. Most studies have found that CABG offers advantages in reducing death and myocardial infarction in people with multivessel blockages compared with PCI.[1] Different modeling studies have come to opposing conclusions on the relative cost-effectiveness of PCI and CABG in people with myocardial ischemia that does not improve with medical treatment.[2][3][4]

Medical uses

Coronary angiography and angioplasty in acute myocardial infarction (left: RCA closed, right: RCA successfully dilated)
Tight, critical stenosis (95%) of the proximal LAD in a patient with Wellens' warning

PCI is used primarily to open a blocked coronary artery and restore arterial blood flow to heart tissue, without requiring open-heart surgery. In patients with a restricted or blocked coronary artery, PCI may be the best option to re-establish blood flow as well as prevent angina (chest pain), myocardial infarctions (heart attacks) and death. Today, PCI usually includes the insertion of stents, such as bare-metal stents, drug-eluting stents, and fully resorbable vascular scaffolds (or naturally dissolving stents). The use of stents has been shown to be important during the first three months after PCI; after that the artery can remain open on its own.[5] This is the premise for developing bioresorbable stents that naturally dissolve after they are no longer needed.

The appropriateness of PCI use depends on many factors. PCI may be appropriate for patients with stable coronary artery disease if they meet certain criteria, such as having any coronary stenosis greater than 50 percent or having angina symptoms that are unresponsive to medical therapy.[6] Although PCI may not provide any greater help in preventing death or myocardial infarction over oral medication for patients with stable coronary artery disease, it likely provides better relief of angina.[7][8]

In patients with acute coronary syndromes, PCI may be appropriate; however, guidelines and best practices are constantly evolving. In patients with severe blockages, such as ST-segment elevation myocardial infarction (STEMI), PCI can be critical to survival as it reduces deaths, myocardial infarctions and angina compared with oral medication.[9] For patients with either non-ST-segment elevation myocardial infarction (nSTEMI) or unstable angina, treatment with medication and/or PCI depends on a patient's risk assessment.[10]

Adverse events

Coronary angioplasty is widely practiced and has a number of risks;[11] however, major procedural complications are uncommon. Coronary angioplasty is usually performed using invasive catheter-based procedures by an interventional cardiologist, a medical doctor with special training in the treatment of the heart.[12]

The patient is usually awake during angioplasty, and chest discomfort may be experienced during the procedure. The patient remains awake in order to monitor the patient's symptoms. If symptoms indicate the procedure is causing ischemia the cardiologist may alter or abort part of the procedure. Bleeding from the insertion point in the groin (femoral artery) or wrist (radial artery) is common, in part due to the use of antiplatelet drugs. Some bruising is therefore to be expected, but occasionally a hematoma may form. This may delay hospital discharge as flow from the artery into the hematoma may continue (pseudoaneurysm) which requires surgical repair. Infection at the skin puncture site is rare and dissection (tearing) of the access blood vessel is uncommon. Allergic reaction to the contrast dye used is possible, but has been reduced with the newer agents. Deterioration of kidney function can occur in patients with pre-existing kidney disease, but kidney failure requiring dialysis is rare. Vascular access complications are less common and less serious when the procedure is performed via the radial artery.[13]

The most serious risks are death, stroke, ventricular fibrillation (non-sustained ventricular tachycardia is common), myocardial infarction (heart attack, MI), and aortic dissection. A heart attack during or shortly after the procedure occurs in 0.3% of cases; this may require emergency coronary artery bypass surgery.[14] Heart muscle injury characterized by elevated levels of CK-MB, troponin I, and troponin T may occur in up to 30% of all PCI procedures. Elevated enzymes have been associated with later clinical outcomes such as higher risk of death, subsequent MI, and need for repeat revascularization procedures.[15][16] Angioplasty carried out shortly after an MI has a risk of causing a stroke, but this is less than the risk of a stroke following thrombolytic drug therapy.[17]

As with any procedure involving the heart, complications can sometimes, though rarely, cause death. The mortality rate during angioplasty is 1.2%.[18] Sometimes chest pain can occur during angioplasty because the balloon briefly blocks off the blood supply to the heart. The risk of complications is higher in:[19]

Procedure

The term balloon angioplasty is commonly used to describe percutaneous coronary intervention, which describes the inflation of a balloon within the coronary artery to crush the plaque into the walls of the artery. While balloon angioplasty is still done as a part of nearly all percutaneous coronary interventions, it is rarely the only procedure performed.

Other procedures done during a percutaneous coronary intervention include:

The angioplasty procedure usually consists of most of the following steps and is performed by a team made up of physicians, physician assistants, nurse practitioners, nurses, radiographers, and cardiac invasive specialists; all of whom have extensive and specialized training in these types of procedures.

  1. Access into the femoral artery in the leg (or, less commonly, into the radial artery or brachial artery in the arm) is created by a device called an "introducer needle". This procedure is often termed percutaneous access.
  2. Once access into the artery is gained, a "sheath introducer" is placed in the opening to keep the artery open and control bleeding.
  3. Through this sheath, a long, flexible, soft plastic tube called a "guiding catheter" is pushed. The tip of the guiding catheter is placed at the mouth of the coronary artery. The guiding catheter also allows for radio-opaque dyes (usually iodine-based) to be injected into the coronary artery, so that the disease state and location can be readily assessed using real time X-ray visualization.
  4. During the X-ray visualization, the cardiologist estimates the size of the coronary artery and selects the type of balloon catheter and coronary guidewire that will be used during the case. Heparin (a "blood thinner" or medicine used to prevent the formation of clots) is given to maintain blood flow. Bivalirudin when used instead of heparin has a higher rate of myocardial infarction but lower rates of bleeding.[20]
  5. The coronary guidewire, which is an extremely thin wire with a radio-opaque flexible tip, is inserted through the guiding catheter and into the coronary artery. While visualizing again by real-time X-ray imaging, the cardiologist guides the wire through the coronary artery to the site of the stenosis or blockage. The tip of the wire is then passed across the blockage. The cardiologist controls the movement and direction of the guidewire by gently manipulating the end that sits outside the patient through twisting of the guidewire.
  6. While the guidewire is in place, it now acts as the pathway to the stenosis. The tip of the angioplasty or balloon catheter is hollow and is then inserted at the back of the guidewire—thus the guidewire is now inside of the angioplasty catheter. The angioplasty catheter is gently pushed forward, until the deflated balloon is inside of the blockage.
  7. The balloon is then inflated, and it compresses the atheromatous plaque and stretches the artery wall to expand.
  8. If a stent was on the balloon, then it will be implanted (left behind) to support the new stretched open position of the artery from the inside.[21]

Types of stents

A coronary stent placed by percutaneous coronary intervention.

Traditional 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 — which may come in response to the stent — that can block the artery. These types of stents have been shown to help prevent restenosis of the artery through physiological 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.[22]

However, in 2006, clinical trials showed a possible connection between drug-eluting stents and an event known as “late stent thrombosis” where the blood clotting inside the stent can occur one or more years after stent implantation. Late stent thrombosis occurs in 0.9% of patients and is fatal in about one-third of cases when the thrombosis occurs.[23] Increased attention to antiplatelet medication duration[10] and new generation stents (such as everolimus-eluting stents)[24] have dramatically reduced concerns about late stent thrombosis.

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.[25]

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 ideal length of time a patient needs to be on dual antiplatelet therapy is not fully determined, but guidelines recommend continuing for 12 months beyond placement unless a patient is at a high risk for bleeding.[26]

Pressure-controlled intermittent coronary sinus occlusion

PCI is used in coronary heart disease to effectively restore perfusion. In ACS (acute coronary syndromes) PPCI (primary percutaneous coronary intervention) restores blood flow in occluded or obstructed coronary arteries according to Braunwald's theorem: time is muscle. Flow in major epicardial coronary arteries however does not mean to increase myocardial blood flow leaving obstructed microcirculation without nutritive flow. Nowadays obstructed microcirculation can effectively cleared by pressure-controlled intermittent coronary sinus occlusion (PICSO) redistributing flow into deprived zones of the myocardium and increasing washout clearing no reflow zones in the myocardium. This treatment, a transcoronary sinus intervention which temporarily occludes the major outflow vein (cardiac vein) by automatically intermittent balloon pressure increase by observing the pressure in the occluded vein redistributes blood flow into affected heart tissue thereby improving microcirculation.[27] PICSO also shows the potential for myocardial salvage and for tissue regeneration.[27]

Usage

Percutaneous coronary angioplasty is one of the most common procedures performed during U.S. hospital stays; it accounted for 3.6% of all operating room procedures performed in 2011.[28] Between 2001 and 2011, however, its volume decreased by 28%, from 773,900 operating procedures performed in 2001 to 560,500 procedures in 2011.[29]

History

Coronary angioplasty, also known as percutaneous transluminal coronary angioplasty (PTCA), because it is done through the skin and through the lumen of the artery, was first developed in 1977 by Andreas Gruentzig. The first procedure took place Friday Sept 16, 1977, at Zurich, Switzerland.[30] Adoption of the procedure accelerated subsequent to Gruentzig's move to Emory University in the United States. Gruentzig's first fellow at Emory was Merril Knudtson, who, by 1981, had already introduced it to Calgary, Alberta, Canada.[31] By the mid-1980s, many leading medical centers throughout the world were adopting the procedure as a treatment for coronary artery disease.

Angioplasty is sometimes erroneously referred to as "Dottering", after Interventional Radiologist, Dr Charles Theodore Dotter, who, together with Dr Melvin P. Judkins, first described angioplasty in 1964.[32] As the range of procedures performed upon coronary artery lumens has widened, the name of the procedure has changed to percutaneous coronary intervention.

Research

Current concepts recognize that after three months the artery has adapted and healed and no longer needs the stent.[5]

References

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