Key Concept: Anesthetic risk is a combination of the effects of the anesthetic agents and, in large part, the skill level of the anesthesiologist.

Modern anesthesia is typically very safe, with an estimated risk of death from anesthesia at 1 per 200,000–300,000 anesthetics [6]. Based on the American Society of Anesthesiologists (ASA) physical status classification system, a normal healthy ASA class 1 patient has a mortality rate of less than 0.03 %. The rate increases to 0.2 % for class 2 patients, 1.2 % for class 3 patients, 8 % for class 4 patients, and 34 % for class 5 patients [7]. Significant perioperative morbidity is also related to ASA status, with a relative risk of 2.2 and 4.4 for ASA classes 3 and 4, respectively [8].

A number of meta-analyses have shown that overall mortality is lower in patients receiving neuraxial anesthesia (epidural or spinal) when compared to general inhalation anesthesia. Much of this difference is due to lower rates of thromboembolic disease, pneumonia, and respiratory depression [9–11]. In general, there is no difference in the rate of cardiac events between general and neuraxial anesthesia, though every effort is made to support the blood pressure during induction of general anesthesia. Patients who are being considered for neuraxial anesthesia for postoperative pain control may also gain additional benefits from the point of view of enhanced recovery, although this has not been consistent in the literature [12].

Several special devices are at the disposal of (and often used by) the anesthesiologist to enhance intraoperative monitoring. These include central venous catheters for volume status, arterial catheter for continuous blood pressure monitoring and frequent blood gas analysis, and pulmonary artery catheterization to monitor cardiac output, pulmonary artery pressure, and pulmonary vascular resistance. Perhaps surprisingly, there is no good evidence that any of these interventions decrease the incidence of perioperative complications. The routine use of pulmonary artery catheters for high-risk patients undergoing noncardiac surgery is not recommended [13, 14]. On the other hand, transesophageal echocardiography is increasingly being used in high-risk patients undergoing high-risk procedures to promote goal-directed therapy [15]. However, the indications for this technology are still evolving and oftentimes anesthesia dependent.

Key Concept: Healthy patients can be screened with a simple questionnaire that includes age, exercise tolerance, social habits, medications, and problems with previous anesthetics. In general, selective preoperative testing should be based on a focused history and physical examination.

Key Concept: Cardiovascular risk is best assessed using one of the well–defined cardiac risk indices. High–risk patients with significant cardiovascular disease may require preoperative stabilization with medical therapy, and in some cases, preoperative revascularization to decrease risk.

Cardiovascular risk assessment is based on an evaluation of specific predictive clinical variables, exercise capacity, and surgery-specific risk. The algorithm for cardiovascular risk assessment is reproduced in Fig. 2.1 [1]. Patients at high risk of cardiovascular events who require emergency surgery may not have time to be fully evaluated or medically optimized due to the urgency of their surgical problem. In this situation, clinical conditions should be documented for monitoring with management and stabilization occurring intraoperatively and in the postoperative period.

In the urgent or elective situation, there are several factors that increase the risk of significant postoperative cardiac events such as myocardial infarction (MI), heart failure, and death. These factors include unstable angina, severe angina or recent MI (within 30 days), decompensated heart failure, significant arrhythmias, and severe valvular heart disease. When these factors are present (especially in combination), a very careful preoperative evaluation is required and may justify a delay in, or even preclude proceeding with, surgery. In addition, there are a number of secondary clinical variables that include a history of ischemic heart disease, cerebral vascular disease, compensated heart failure or prior heart failure, diabetes mellitus, and renal insufficiency, which are also predictive for cardiovascular morbidity [37]. While many of them are incorporated into the clinical risk indexes outlined below to give an overall risk score for the patient, they do have independent associations with worse outcomes as well.

An evaluation of patient-specific risk also includes an assessment of exercise tolerance. As noted previously, poor exercise tolerance has been defined as the inability to walk two to four blocks or climb two flights of stairs at a normal pace due to the development of dyspnea, angina, or excessive fatigue. This translates to a metabolic equivalent of ~4 (4 MET), and failure to achieve this is predictive of in-hospital perioperative risk. Additional activities with a similar metabolic equivalent include carrying objects of 15–20 lb and playing golf or doubles tennis.

The overall perioperative cardiovascular risk for each individual patient is determined using one of several cardiac risk indexes. In 1977, Goldman was one of the first to develop a cardiac risk index using nine variables to predict the development of cardiac complications [38]. Since then, several others have come along—some cardiac-specific, and others more general (i.e., ASA Classification [39, 70]; Table 2.3). Earlier, we introduced the Revised Cardiac Risk Index (RCRI) or Lee Index, as it is one of the most widely used due to its simplicity and clinical utility [40] (Table 2.2). It is the primary index applied at our center and is based on the presence or absence of six predictive factors: high–risk surgery, ischemic heart disease, congestive heart failure, cerebrovascular disease, diabetes mellitus, and renal dysfunction. Patients receive one point for each risk factor that is present to give a cumulative index score. The rate of development of a major cardiac event—defined as myocardial infarction, pulmonary edema, ventricular fibrillation/cardiac arrest, and complete heart block—is estimated to be 0.4 % (95 % CI 0.1–0.8 %), 1 % (95 % CI 0.5–1.4 %), 2.4 % (95 % CI 1.3–3.5 %), and 5.4 % (95 % CI 2.8–7.9 %) for scores of 0, 1, 2, and ≥3, respectively [41, 42]. Using the AHA algorithm, patients at high risk for cardiac complications (score ≥3) should undergo noninvasive cardiac (stress) testing. If severe myocardial ischemia is identified, coronary revascularization should be considered prior to planned surgery (if possible), in addition to preventative medical strategies outlined below.

Recently, a new predictive risk model for perioperative myocardial infarction/cardiac arrest was constructed from the American College of Surgeons National Surgery Quality Improvement Program (NSQIP) database [43]. This model is based on a very large patient cohort where more recent preventive and interventional cardiac strategies were applied. On multivariate regression analysis, significant predictive variables included type of surgery, dependent functional class, abnormal creatinine, ASA class, and increased age. This model is not as well known; thus, many internists are not comfortable using it. However, when compared directly to the RCRI model, it demonstrated higher predictive accuracy. An online calculator has been created which makes it easy to apply by the surgeon to determine individual risk [44].

Perioperative medical therapy for cardiac risk reduction includes B-blockers, statins, and aspirin. High-risk patients or those who take these medications preoperatively require medical consultation. Based on recent evidence, preoperative B-blocker use has been limited to specific risk groups and must be introduced gradually. Despite good evidence for the beneficial effect of B-blockers and statins [45, 46], the evidence for the perioperative use of aspirin and/or thienopyridine for the reduction of cardiac risk is less clear due to an increased risk of perioperative bleeding. While aspirin alone is safe, the combination of aspirin with thienopyridine is associated with an increased risk of perioperative bleeding and transfusion. To reduce the risk of bleeding, thienopyridine should be discontinued 5–7 days prior to surgery and restarted as soon as the risk of postoperative bleeding has decreased.

High-risk patients with severe cardiac ischemia may be candidates for preoperative coronary revascularization. Patients with left main stem or three-vessel CAD associated with poor left ventricular function have a recognized survival advantage with either coronary artery bypass (CABG) or percutaneous coronary intervention (PCI) including balloon angioplasty and/or stent placement. The benefits and risks of revascularization must be factored into the decision-making process. CABG has a higher procedural risk than PCI. However, PCI with stent placement is associated with an increased risk of perioperative bleeding due to the use of dual antiplatelet agents, which, if stopped prematurely, may result in stent occlusion. Ideally, colorectal surgery should be delayed ~30–45 days after placement of a bare metal stent and 1 year following a drug-eluding stent. This may not be practical in a patient with a near obstructing cancer or in the situation of a narrow therapeutic window following chemoradiation. Patients who require surgery within a month of coronary revascularization should undergo either an angioplasty without stent placement or, in select circumstances, a CABG. The colorectal surgeon must be involved in these complex decisions, especially when determining the urgency of the situation.