FIGURE 39-2. Typical overlap in vascular disease affecting different organ systems. PAD = peripheral arterial disease.

2. In the first 6 weeks after coronary stent placement, noncardiac surgery carries considerable risks. There are two basic types of stents: bare metal stents and drug-eluting stents. Although drug-eluting stents have a reduced incidence of restenosis, they are slow to endothelialize, and the exposed stent material remains thrombogenic far longer than bare metal stents. Therefore, the duration of dual antiplatelet therapy (aspirin 325 mg/day and clopidogrel 75 mg/day) differs: 1 month for bare-metal stents, 12 months or more for drug-eluting stents.

3. Guidelines suggest continuing aspirin therapy in all patients with a coronary stent and discontinuing clopidogrel for as short a time interval as possible for patients with bare-metal stents for an <30 days or drug-eluting stents for <1 year.

4. Two distinct types of perioperative MI (PMI)–“early” and “delayed”–occurring after vascular surgery have been identified.

a. Early PMI resembles that of acute nonsurgical MI and is probably attributable to acute coronary occlusion resulting from plaque rupture and thrombosis.

b. The “delayed PMI” is associated with sustained elevation of heart rate, absence of chest pain, and prolonged premonitory episodes of ST segment depression before overt MI. The delayed PMI resembles that resulting from increase in oxygen demand in the setting of fixed coronary stenosis.

5. Guidelines from the American Heart Association and American College of Cardiology classify the clinical predictors of increased perioperative cardiovascular risk (MI, congestive heart failure, and death) as “major,” “intermediate,” and “minor.” (Table 39-2).

B. Preoperative Coronary Revascularization. Myocardial revascularization may have long-term benefits in patients with triple-vessel coronary disease or poor left ventricular function. However, mortality rates associated with these techniques are consistently higher in patients with peripheral vascular disease compared with those without. Whether preoperative coronary revascularization actually protects against perioperative cardiac events is controversial.

III. OTHER MEDICAL PROBLEMS IN VASCULAR SURGERY (Table 39-3)

TABLE 39-2 PHARMACOLOGIC PROPHYLAXIS AGAINST ACUTE VASCULAR EVENTS IN PATIENTS UNDERGOING VASCULAR SURGERY

*Class I: evidence or general agreement that treatment is useful or effective.
Class IIa: weight of evidence or opinion is in favor of usefulness or efficacy.
Class IIb: usefulness or efficacy is less well established by evidence or opinion.
Class III: evidence or general agreement that the procedure or treatment is not useful or effective or in some cases may be harmful.
ACC = American College of Cardiology; AHA = American Heart Association; POISE = Perioperative Ischemic Evaluation Study.

TABLE 39-3 OTHER MEDICAL PROBLEMS IN VASCULAR SURGERY PATIENTS

Correcting systemic hypertension

Undiagnosed diabetes and abnormal blood glucose tolerance (aggressive management of blood glucose concentrations is controversial with some studies showing benefit and others increased mortality rates)

Hypercoagulable states

Heparin-induced thrombocytopenia

IV. ORGAN PROTECTION IN VASCULAR SURGERY PATIENTS

A. Ischemia-Reperfusion Injury in the Vascular Surgery Patient: Fundamental Concepts

1. Ischemia–reperfusion injury (IRI) is the sine qua non of organ failure in vascular surgery patients, and the techniques inherent to vascular surgery create a highly specific milieu that promotes multiorgan ischemia–reperfusion.

2. IRI, particularly in vascular surgery patients, is a highly complex micro- and macrophysiologic process; this helps explain why single interventions aimed at single components of this process (e.g., increasing blood pressure to maximize flow) have proven ineffective in clinical studies.

B. Prevention of Myocardial Injury (Table 39-4)

C. Prevention of Kidney Injury. Perioperative acute kidney injury (AKI) is a common complication of vascular surgery and is associated with high morbidity and mortality (incidence of AKI is between 16% and 22% of patients undergoing aortic surgery). Preoperative renal dysfunction is the most powerful predictor of postoperative renal dysfunction.

1. Pharmacologic Approaches. There is currently no clinical evidence to support the benefit of any pharmacologic intervention or protection strategy (mannitol, loop diuretics, dopamine).

2. Nonpharmacologic Approaches. Multiple nonpharmacologic strategies have been used to prevent renal injury during aortic surgery. It was hoped that morbidity and mortality from endovascular aneurysm repair (EVAR) would be reduced compared with open aortic aneurysm repair. (Trials found no long-term difference in renal function between open repair and EVAR.)

TABLE 39-4 PREVENTION OF PERIOPERATIVE MYOCARDIAL INFARCTION IN VASCULAR SURGERY PATIENTS

Pharmacologic Approaches

Administration of β-blockers (may not be effective in lower risk patients or if heart rate is well controlled)

Preoperative oral therapy 7–30 d with atenolol or metoprolol

Intraoperatively and postoperatively intravenous metoprolol or esmolol titrated to heart rate and blood pressure)

α₂-Agonists (clonidine or mivazerol): not investigated as cardioprotective agents in the perioperative environment

Statins: Initiate about 30 d preoperatively and continue 2–4 wk after surgery

ACE inhibitors: Risk is perioperative hypotensive effects

Calcium channel blockers: Not recommended for perioperative cardioprotection

Nitroglycerin: May provoke or exacerbate hypotension with reflex tachycardia; not recommended for perioperative cardioprotection

Anesthetic technique (unproven)

Nonpharmacologic Approaches

Epidural analgesia

Transfusion strategy: May be more important to maintain hemoglobin levels in β-blocked patients

Maintenance of normothermia in the early postoperative period

Endovascular aneurysm repair: Not proven to reduce cardiac risk relative to open repair

ACE = angiotensin-converting enzyme; IV = intravenous.

D. Prevention of Pulmonary Complications. Pulmonary complications (pneumonia, respiratory failure) are common after major vascular surgery (10%–30% of AAA patients) and are associated with increased mortality and length of stay. Postoperative lung expansion with continuous positive airway pressure or incentive spirometry and postoperative thoracic epidural analgesia reduce perioperative respiratory complications.

E. Protection of the Central Nervous System and Spinal Cord (Table 39-5)

TABLE 39-5 PROTECTION OF THE CENTRAL NERVOUS SYSTEM AND SPINAL CORD

Prevention of perioperative delirium (CNS failure)

Common after vascular surgery and an independent risk factor for mortality

Alcohol withdrawal a common cause

Prevention of perioperative stroke

Carotid revascularization before major vascular surgery

Atrial fibrillation

Antiplatelet therapy

Prevention of spinal cord ischemia

Short cross-clamping time

High perfusion pressures

Gott shunts (risk of atheroemboli)

Partial bypass

CSF drainage

Prevention of perioperative stroke

Carotid revascularization before major vascular surgery

Atrial fibrillation

Antiplatelet therapy

CNS = central nervous system; CSF = cerebrospinal fluid.

V. CAROTID ENDARTERECTOMY. Carotid disease is usually a problem of embolization (transient attacks of monocular blindness, transient ischemic attacks) and less often occlusion or insufficiency (cervical bruit). The most common noninvasive test is carotid duplex ultrasonography followed by confirmatory angiography.

A. Management of Asymptomatic Carotid Stenosis. The optimal treatment of asymptomatic carotid stenosis is controversial. (Many question the role of carotid endarterectomy [CEA] in asymptomatic patients.)

B. Management of Symptomatic Carotid Stenosis. CEA, in conjunction with aspirin therapy, has proven superior to medical therapy alone

C. Preoperative Evaluation and Preparation for Carotid Endarterectomy.

1. Most patients presenting for CEA will be taking aspirin, which should be continued throughout the perioperative period.

2. Many patients will also be taking another antiplatelet therapy (clopidogrel). The benefit of continuing other agents at the time of CEA must be balanced against the risk of bleeding.

D. Monitoring and Preserving Neurologic Integrity

1. The intraoperative goals of protecting the brain and the heart often conflict. (Increasing arterial blood pressure to augment cerebral blood flow increases the oxygen demand of the heart.) The rationale behind maintaining a stable, high-normal blood pressure throughout the procedure is based on the assumption that blood vessels in ischemic or hypoperfused areas of brain have lost normal autoregulation. Nonetheless, hypotension and hypoperfusion are not the most common cause of stroke after CEA; embolic events may be even more important and often occur postoperatively.

2. On balance, it is probably beneficial in the absence of neurologic monitoring (bispectral index, electroencephalography, Transcutaneous Doppler [TCD], SSEP) to avoid hypotension during the period of cross-clamping, particularly if no shunt is used. Intravenous fluid and vasopressors such as phenylephrine can be used to maintain blood pressure between normal and 20% above baseline. (Augmentation of blood pressure has been associated with an increased incidence of MI.)

3. If information from the awake patient or reliable monitoring shows good cerebral blood flow, the anesthesiologist may choose to use less vasopressor and to maintain a lower blood pressure during the period of temporary carotid occlusion than would be otherwise feasible.

4. Hypercapnia during CEA may be detrimental if it dilates vessels in normal areas of the brain while vessels in ischemic brain areas that are already maximally dilated cannot respond. The net effect, then, is a “steal” phenomenon (diversion of blood flow from hypoperfused brain regions to normally perfused brain regions). Conversely, hypocarbia may cause vasoconstriction and extend any area of cerebral ischemia. Most authorities therefore recommend the maintenance of normocarbia. Most recommend maintenance of normocarbia.

5. Almost all commonly used anesthetic agents reduce cerebral metabolism, thereby decreasing the brain’s requirements for oxygen, yet the notion that reduced cerebral metabolism is associated with cerebral protection has been challenged.

a. Barbiturates may offer a degree of brain protection during periods of regional ischemia.

b. Both etomidate and propofol decrease brain electrical activity and thus decrease cellular oxygen requirements. Etomidate preserves cardiovascular stability and may be beneficial in a patient population whose cardiac reserves are often limited. Propofol also allows rapid awakening of the patient and neurologic assessment at the end of surgery.

6. Hypothermia can depress neuronal activity sufficiently to decrease cellular oxygen requirements below the minimum levels normally required for continued cell viability. In theory, hypothermia represents the most effective method of cerebral protection. Even a mild decrease in temperature of about 2° to 3°C at the time of arterial hypoxemia may reduce ischemic damage to the brain.

7. Surgeons who never use shunts usually rely on expedient surgery to avoid neurologic problems and do not report worse overall outcome statistics than those who use shunts. Placement of a shunt is associated with an embolism-related stroke rate of at least 0.7% from the dislodgment and embolization of atheroma.

E. Anesthetic and Monitoring Choices for Elective Surgery (Table 39-6)

F. Carotid angioplasty and stenting is usually performed in the vascular interventional suite by a team involving vascular surgeons, cardiologists, or radiologists. (Anesthesiologists may be asked to provide sedation and monitoring in complex cases.) The patient needs to be arousable and responsive so that serial neurologic examinations can be conducted.

1. Cerebral emboli are a risk of angioplasty (protect with proximal flow blockage and distal filters).

2. Periprocedural antiplatelet therapy (aspirin, clopidogrel, or ticlopidine) is the standard of care.

G. Postoperative Management (Table 39-7)

H. Management of Emergent Carotid Surgery

1. The patient who awakens with a major new neurologic deficit or who develops a suspected stroke in the immediate postoperative period represents a surgical emergency.

2. For patients undergoing neck exploration for a wound hematoma after CEA, a tracheostomy or cricothyroidotomy tray should be immediately available.

3. Esmolol is particularly useful to control hyperdynamic cardiovascular responses during awake intubation.

TABLE 39-6 PREVENTION OF PERIOPERATIVE MYOCARDIAL INFARCTION IN VASCULAR SURGERY PATIENTS

Intraarterial catheter

ECG monitoring: includes leads II and V₅ for ST-T segment assessment; TEE in high-risk patients

Midazolam (if sedation is necessary)

Determine baseline blood pressure and heart rate from preadmission and admission (maintain hemodynamics within this range intraoperatively)

Continue antianginal, antihypertensive and antiplatelet medications (the exception is clopidogrel, which is stopped 1–5 days preoperatively)

Limit fluid administration to 10 mL/kg (fluid overload may contribute to postoperative hypertension)

Avoid long-lasting opioids that can depress respiration and confound neurologic assessment (remifentanil is an alternative)

Maintain light general anesthesia (permits EEG monitoring and blood pressure maintenance)

Vasopressors to treat hypotension or EEG changes

Extubation at conclusion of surgery

Evaluate neurologic integrity in the operating room (new deficits may require noninvasive imaging, contrast angiography, and/or surgical re-exploration)

Regional anesthesia: sensory blockade of C2–C4 dermatomes with a superficial cervical plexus block (no difference in rate of stroke, MI, or mortality after 30 days with regional vs. general anesthesia)

EEG = electroencephalography; MI = myocardial infarction; TEE = transesophageal echocardiography.

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