Coronary artery bypass grafting (CABG) has been the mainstay for treatment of coronary artery disease (CAD) for several decades. Various options for conduits have been attempted and studied in search of the best vessel to optimize surgical outcomes. The literature describes multiple conduit options, each of which has their particular benefits and complication rates. The saphenous vein graft, for example, has been well documented in the literature to be prone to atherosclerotic changes and is therefore inferior in long-term patency rates compared to internal mammary artery (IMA) grafts. The gastroepiploic artery graft is another conduit option. It was described in the late 1960s in Vineberg’s procedure performed by Bailey et al. where indirect myocardial revascularization was done using the right gastroepiploic artery (GEA). Sterling Edwards et al. in the late 1970s attempted a direct anastomosis of the GEA to the right coronary artery (RCA). Since then the GEA graft has been utilized as an alternative graft in several other documented landmark procedures. It is these cases that depict the various CABG anastomosis techniques that can be performed using the GEA. The GEA CABG surgery has the benefit of long-term patency and has been shown to provide optimal postoperative quality of life. This chapter will discuss in detail the anatomy of the GEA, indications for CABG with GEA as well as contraindications, the surgical technique, possible complications, and clinical significance.
The right GEA is the largest terminal branch of the gastroduodenal artery (GDA) which is a branch of the hepatic artery. At times, it arises from the left hepatic artery or the celiac trunk, or rarely from the superior mesenteric artery. The right GEA reaches nearly half to two-thirds of the greater curvature of the stomach in most people and may form a communication with the left GEA. The diameter of the right GEA is about 3 mm or greater at its origin, and 1.5 to 2 mm at the middle of the greater curvature of the stomach, rendering it suitable for CABG. Histologically, the GEA is a muscular artery as it has several smooth muscle cells in the tunica media making it susceptible to spasm when handled surgically. The GEA is also found to be less prone to development of atherosclerosis than other coronary arteries. The GEA contracts more powerfully in response to vasoactive drugs including ergonovine, serotonin, and phenylephrine than the IMA, hence it is important to prevent spasm of the GEA caused by adrenergic agents or platelet aggregators. Histamine causes dilation of the GEA, and its blood flow is shown to increase after a meal. It is these properties that make the GEA a great option for a conduit for CABG.
Indications for CABG using the GEA include but are not limited to the following:
There are no absolute contraindications for CABG. Relative contraindications include the following:
Equipment for CABG using GEA graft is similar to other CABG procedures, and includes but is not limited to the following:
Recommend smoking cessation for at least 8 weeks prior to the procedure if possible. Hold any P2Y12 inhibitors including clopidogrel at least 5 days before the procedure. On the day of the procedure, intravenous antibiotics should be administered prior to CABG. As this is an invasive surgery, general anesthesia should be administered.
A median sternotomy incision is extended inferiorly around 5-6 cm longer than the standard incision for CABG, opening the peritoneum and the stomach delivered into the surgical field. The GEA is identified, traced, and handled very gently to prevent spasm. It is then mobilized from the greater curvature of the stomach as a pedicle with surrounding tissue or skeletonized keeping the pedicle as long as possible. Electrocautery is used to achieve hemostasis to prevent hematoma formation in the pedicle and to cauterize vessels in the omentum. Silk ligatures are used for branch vessels to secure hemostasis. The GEA is then divided distally and has diluted papaverine hydrochloride injected into its lumen. The distal end is later clamped, which achieves good caliber and adequate distension of the GEA due to papaverine and the effect of its own blood pressure, which is important to achieve a satisfactory anastomosis. The length of the graft is decided by calibrating the distance from the anastomotic site. Approximately 2-3 cm of the artery is skeletonized, and the gastroepiploic vein is ligated. Harmonic scalpel is used to harvest the GEA. The greater omentum is opened, its anterior layer divided and the GEA traced entirely in order to cauterize all its small gastric and omental branches. After ensuring thorough hemostasis, the skeletonized GEA is enveloped in papaverine soaked sponge to prevent spasm and remain relaxed. Thereafter, a small incision is made in the anterior aspect of the diaphragm through which the skeletonized GEA is brought up into the pericardial cavity traversing the anterior surface of the stomach and the liver. The end of the pedicle is then transfixed to the anterior edge of the diaphragm to ensure fixity.
Under cardioplegic arrest or an off-pump beating heart, the GEA and the coronary artery anastomosis is performed. Using a 7-0 or 8-0 polypropylene suture a few running sutures are placed at the heel of the coronary artery and the GEA. Thereafter the rest of the anastomosis is completed using a single continuous suture. The anastomosis could be antegrade or retrograde depending on the site and artery involved. Hemostasis is confirmed before the release of the aortic cross-clamp. It is imperative to avoid twisting or kinking of the GEA due to improper fixation near the peri-anastomotic site. The pedicle of the GEA is now fixed to the epicardium. Thorough hemostasis is performed, the patient weaned off cardiopulmonary bypass (CPB), and the closing of the chest and abdominal wounds takes place. A drain may be placed in the abdominal cavity if required. The patient should be monitored in the immediate post-operative period in the intensive care unit usually for about 1 week.
The right gastroepiploic artery (GEA) is an excellent conduit for CABG. Extensive studies have shown that this artery undergoes minimal atherosclerotic changes and does not increase surgical complications, either cardiac or abdominal. It also does not induce gastric ischemic after mobilization and has survival and patency rates comparable to the internal mammary artery (IMA) grafts. Hence the GEA graft is considered to be safe and a technically sound arterial conduit for CABG.
Coronary artery bypass graft (CABG) is a complicated surgical procedure requiring precision to detail and care in the pre-operative period, intra-operative period, and post-operative period. Furthermore, It is physically strenuous and a life-changing event for most patients. Therefore, it is imperative to have systems in place to ensure the completion of all aspects surrounding the pre-operative management, intra-operative care, and post-operative care including cardiac rehabilitation. Beginning with the pre-operative care, in addition to covering all of the risks and benefits of the procedure with the patient and assessing understanding, screening must be done to ensure the patient meets the requirements for CABG. Just as in any other surgical procedure, proper sterile technique is fundamental to the outcome. Intra-operative care should be attending to by a trained cardiothoracic surgeon (CTS) as well a board-certified anesthesiologist whose job is to monitor the patient's intraoperative hemodynamics closely. In the post-operative period, which might very well be the most crucial period according to many CTS, the patient should be monitored regularly for post-operative complications. Recovery should take about 6 weeks at home following by cardiac rehabilitation and strength training. With all the details surrounding CABG, it is now recommended to have an interprofessional care team approach including a primary care physician, cardiac rehabilitation specialist, a cardiac nurse, and cardiac pharmacist to enhance patient-centered care and optimize procedural success. Studies have shown that the proper care coordination among health professionals and access to post-operative services does improve surgical outcomes. [level1]
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