Anesthesia and Obesity

Brenda A. Bucklin

Ana Fernandez-Bustamante

Key Points

Neck circumference is the single best predictor of problematic intubation in morbidly obese patients. A larger neck circumference is associated with male sex, higher Mallampati score, grade 3 laryngoscopic views, and obstructive sleep apnea.

Because obese patients often have limited exercise tolerance they may appear asymptomatic even though they have significant cardiovascular disease.

Obstructive sleep apnea is common in obese patients and predisposes to airway management difficulties during anesthesia.

Elevated liver function tests (mostly elevated alanine aminotransferase) are seen in many obese patients, but no clear correlation exists between abnormalities of routine liver function tests and the capacity of the liver to metabolize drugs.

Forearm blood pressure is a fairly good predictor of upper arm blood pressure in most patients, but in obese patients, forearm measurements with a standard cuff may overestimate both systolic and diastolic blood pressures.

The head-elevated laryngoscopy position elevates the obese patient’s head, upper body, and shoulders above the chest and can improve visualization for laryngoscopy and tracheal intubation.

Larger doses of induction agents may be required by obese patients because blood volume, muscle mass, and cardiac output increase linearly with the degree of obesity. An increased dose of succinylcholine is necessary because of an increase in pseudocholinesterase activity.

Positive end-expiratory pressure is the only ventilatory parameter that has consistently been shown to improve respiratory function in obese patients but it decreases venous return, cardiac output, and subsequent oxygen delivery.

Prompt but safe extubation reduces the likelihood that the morbidly obese patient will become ventilator-dependent, especially in patients with cardiopulmonary disease.

Morbid obesity is a major independent risk factor for deep venous thrombosis and sudden death from acute postoperative pulmonary embolism. Early mobilization of the morbidly obese patient is often difficult but critically important in the prevention of postoperative complications.

Because of the risk of perioperative hypoxemia and apnea in obese patients, postoperative pain management should include opioid-sparing multimodal analgesic techniques. Regional anesthetic techniques reduce the risk of opioid-related complications.

Obese patients who have received either neuraxial or parenteral opioids require careful postoperative monitoring. Delayed respiratory depression with centrally administered neuraxial opioids, when coupled with a potentially difficult airway in the obese patient, suggests that close monitoring is prudent.

Definition and Epidemiology

Introduction

The World Health Organization defines obesity as a condition with excess body fat to the extent that health and well-being are adversely affected.¹ Obesity is reaching epidemic proportions worldwide. For the first time in history, recent estimates suggest that the number of obese individuals now exceeds the number of underweight individuals. About one-third of Americans (33.8%) are currently obese.² The prevalence of obesity in the United States is unevenly distributed geographically, by race and ethnicity and by socioeconomic status. The overall trend is, however, to keep increasing. The prevalence of obesity is predicted to reach about 50% by 2030.³ The Centers for Disease Control and Prevention (CDC) monitor the epidemiology of obesity and publish periodically updated data at http://www.cdc.gov/obesity/.

Obesity-related conditions including cardiovascular accidents, insulin- and noninsulin-dependent diabetes, and some types of cancer are the leading causes of death in this population.⁴ Although there has been an exponential increase in the number of bariatric procedures performed, obese and morbidly obese patients undergo all types of surgical procedures. Surgery in this patient population is considered high-risk but careful planning, preoperative risk assessment, proper anesthetic management, strict venothrombotic event prevention, and effective postoperative pain control will all help to reduce the risk. With appropriate perioperative management, obese surgical patients can achieve safe and effective surgical outcomes.

The definition of obesity includes the presence of excessive body weight for the patient’s age, gender, and height, and is often based on the following concepts. Ideal body weight (IBW) is a concept originated by life insurance companies by referencing height–weight tables. It is the weight associated with the lowest mortality rate for a given height and gender and can be estimated using Broca’s index:

where x is 100 for adult males and 105 for adult females.

Predicted body weight (PBW) is a concept similar to IBW, and is more commonly used in the medical literature. PBW is usually calculated with the following formulas in adults⁵:

Lean body weight (LBW) is the total body weight (TBW) minus the adipose tissue. It is a combination of body cell mass, extracellular water, and nonfat connective tissue. It approximates 80% and 75% of TBW for males and females, respectively, although more accurate formulas have been proposed.⁶,⁷ In morbidly obese patients, increasing the IBW by 20% to 30% gives an estimate of LBW. In nonobese and nonmuscular individuals, TBW approximates IBW.⁸

In clinical practice it is common to utilize the Body mass index (BMI), also called Quetelet’s index, to estimate the degree of obesity. The BMI is determined using the patient’s measured weight (in kilograms) and height (in meters) and is calculated as follows:

Obesity is defined as having a BMI ≥30 kg/m². Obesity is further classified according to systemic disease risk (Table 44-1). Morbid obesity, defined as a BMI ≥40 kg/m², can also be further classified into super obesity (BMI ≥50 kg/m²) and super-super obesity (BMI ≥60 kg/m²).⁹ BMI differentiates obese from nonobese adults and it estimates body fat because it adjusts for height while strongly correlating with body weight; however, it cannot distinguish between overweight and overfat, as heavily muscled individuals can be easily classified as overweight using BMI. Therefore, other factors such as age, fat content, and distribution (i.e., waist circumference and waist-to-hip ratio) should be taken into consideration, along with other health risk predictors that use the concept of BMI.¹⁰

The anatomic distribution of body fat has associated pathophysiologic implications.¹¹,¹² In android (central) obesity, adipose tissue is located predominantly in the upper body (truncal distribution) and is associated with increased oxygen consumption and an increased incidence of cardiovascular disease. Visceral fat is particularly associated with cardiovascular disease and left ventricular dysfunction. In gynecoid (peripheral) obesity, adipose tissue is located predominantly in the hips, buttocks, and thighs.
This fat is less metabolically active so it is less closely associated with cardiovascular disease. Body circumference indices such as waist circumference, waist-to-height ratio, and waist-to-hip ratio help to classify these patterns of obesity (e.g., android vs. gynecoid obesity) and correlate with mortality and the risk for developing obesity-related diseases. Waist circumference correlates with abdominal fat and is an independent risk predictor of disease.

Table 44-1. Classification of Obesity and Systemic Disease Risk According to Waist Circumference

BMI (kg/m²)	Description	Risk of Systemic Disease (Small vs. Large Waist Circumference)
		Male: <102 cm	Male: ≥102 cm
		Female: <88 cm	Female: ≥88 cm
<18.5	Underweight
18.5–24.9	Normal
25–29.9	Overweight
30–34.9	Obesity (class I)	Average	Average
35–39.9	Obesity (class II)	Increased	High
≥40	Morbid obesity (class III)	High	Very high
≥50	Super obesity	Very high	Very high
≥60	Super-super obesity	Extremely high	Extremely high
BMI, body mass index.

Management of Obesity

Medical Therapy

The indications for pharmacologic treatment include a BMI ≥30 kg/m² or a BMI between 27 and 29.9 kg/m² in conjunction with an obesity-related medical complication. Lifestyle counseling is still the most effective tool for long-term weight loss, but it can be combined with the use of medications.¹³,¹⁴ Medications used to treat obesity are formulated to reduce energy intake, increase energy utilization, or decrease absorption of nutrients. The only currently FDA-approved antiobesity medications are phentermine and orlistat.¹⁵ Phentermine (Adipex-P) is a sympathomimetic drug that decreases appetite. Although it is only approved for 3 months use, it can induce tachycardia, palpitations, hypertension, as well as dependence, abuse, and withdrawal symptoms. It is no longer combined with fenfluramine (Phen-Fen) due to concerns of pulmonary hypertension and valvular heart disease,¹⁶ but is being explored in combination with topiramate (Topamax).¹⁷ This combination often causes dry mouth, paresthesias, constipation, insomnia, and dizziness. Orlistat (OTC Alli, prescribed Xenical) or tetrahydrolipstatin, blocks the absorption of dietary fat by inhibiting lipases in the gastrointestinal tract. It leads to weight loss and to improvement of blood pressure, fasting blood glucose levels, and lipid profile.¹⁸ Fat malabsorption causes common complaints of oily spotting, liquid stools, fecal urgency, flatulence, and abdominal cramping. Chronic use of orlistat may result in fat-soluble vitamin deficiency. A prolonged prothrombin time with a normal partial thromboplastin time during orlistat treatment may reflect vitamin K deficiency and this coagulopathy should be corrected 6 to 24 hours before elective surgery.¹⁹

A variety of over the counter preparations, plant extracts, or herbs are often used by patients to combat obesity. Substances found in these preparations that are allegedly thought to promote fat loss include pancreatic lipase inhibitors (caffeine, green or black tea), appetite suppressants (hoodia, Korean ginseng, ephedra, sunflower oil), stimulants of energy expenditure (acai berry, caffeine), and regulators of lipid metabolism (soybean, fish oil, oolong tea, caffeine).²⁰ The American Society of Anesthesiologists (ASA) warns patients to tell their anesthesiologists about medications they are taking, including vitamins, herbs and other supplements, since these products may interfere with anesthesia or cause complications during surgery.²¹

Surgical Therapy (Bariatric Surgery)

Bariatric surgery is currently the most effective treatment for morbid (class III) obesity. Several guidelines exist for determining patient eligibility for bariatric surgery. Most agree that acceptable patients for surgery are those with a BMI >40 kg/m² or BMI >35 kg/m² and/or those patients with obesity-related comorbidities not controlled with medical therapy.²² Procedures are grouped into three classifications. Malabsorptive procedures include jejunoileal bypass and biliopancreatic diversion, and are rarely used nowadays. Restrictive procedures include vertical-banded gastroplasty and adjustable gastric banding. Combined procedures include Roux-en-Y gastric bypass (RYGB), which combines gastric restriction with a minimal degree of malabsorption. RYGB, adjustable gastric banding, and vertical-banded gastroplasty can all be performed laparoscopically. Laparoscopic bariatric surgery is associated with less postoperative pain, lower morbidity, faster recovery, and less “third-spacing” of fluid.²³ RYGB is the most effective bariatric procedure to produce safe short- and long-term weight loss in severely obese patients. With RYGB, patients lose an average of 50% to 60% excess body weight and show a BMI decrease of approximately 10 kg/m² during the first 12 to 24 postoperative months. Type II diabetes resolves in a majority of patients. Laparoscopic adjustable gastric banding (LAGB) is a restrictive gastric operation that utilizes an adjustable inflatable band to alter stomach capacity for individual weight loss needs. Vertical-banded or sleeve gastroplasty also restricts food intake.

Less invasive bariatric techniques are being developed. An implantable gastric stimulator (IGS) is placed laparoscopically and emits electrical impulses to stimulate the gastric smooth muscle to stop peristalsis so that the patient feels full. The IGS can be adversely affected by defibrillation, electrocautery, lithotripsy, magnetic resonance imaging, and therapeutic radiation. Intragastric balloons and prostheses, at different experimental stages, are placed endoscopically as a temporary measure to increase satiety.²⁴ Adequate control of postoperative nausea and vomiting is critical to avoid possible lead and balloon dislodgement. Although apparently simple and safe as bariatric procedures, their efficacy for weight loss is still questioned.²²,²⁵

Pathophysiology

Obesity can have an adverse effect on multiple organ systems. Table 44-2 provides a list of the most relevant organ systems with implications for clinical management. These systems will be discussed separately in this section.

Respiratory System

Fat accumulation on the thorax and abdomen decreases chest wall and lung compliance. Decreased lung compliance is partially explained by increased pulmonary blood volume related to an overall increase in blood volume. Increased elastic resistance and decreased compliance of the chest wall are further reduced while supine, leading to shallow and rapid breathing, an increased work of breathing, and limited maximum ventilatory capacity. Respiratory muscle efficiency is below normal in obese individuals. Decreased pulmonary compliance leads to decreased functional residual capacity (FRC), vital capacity, and total lung capacity. Reduction in FRC is primarily a result of reduced expiratory reserve volume (ERV), but the relationship between FRC and closing capacity, the volume at which small airways begin to close, is adversely affected (Fig. 44-1). Decreases in FRC and ERV are the most commonly reported abnormalities of pulmonary function in obese patients.²⁶,²⁷ Residual volume and closing capacity are unchanged. Reduced FRC (due to decreased ERV) can result in lung volumes below closing capacity in the course of normal tidal ventilation, leading to small airway closure, ventilation–perfusion mismatch, right-to-left shunting, and arterial hypoxemia. Anesthesia and supine positioning worsen this situation such that up to a 50% reduction in FRC occurs in the obese anesthetized patient compared with 20% in the nonobese individual. Forced expiratory volume in 1 second and forced vital capacity are usually within normal limits. ERV is the most sensitive indicator of the effect of obesity on pulmonary function.

Table 44-2. Anesthetic Implications of Obesity

System	Key Concerns
Respiratory	Increased risk of perioperative hypoxemia Careful monitoring needed Use supplemental oxygen Use CPAP (if/when indicated) Use nonsupine positioning (if possible) Exercise extreme caution when administering respiratory depressants
Cardiovascular	Increased blood volume, cardiac output, left ventricular thickness Increased proinflammatory and prothrombotic mediators Higher perioperative complications related to hypertension, thromboembolic events and left ventricular diastolic dysfunction
Gastrointestinal	Risk of regurgitation Higher gastric volume and lower pH increases risk of severe pneumonitis should aspiration occur Current fasting preoperative guidelines (6 h for solids, 2 h for clear liquids) are acceptable Preoperative assessment of liver function is recommended
Endocrine/metabolic	High prevalence of hyperglycemia, insulin resistance and diabetes Close perioperative glucose monitoring Metabolic syndrome (combination of central obesity, hypertension, dyslipidemia and impaired glucose metabolism) is frequent and doubles cardiovascular risk
Genitourinary	Increased risk of renal disease Higher incidence of preeclampsia and eclampsia
Neurologic	Careful positioning with extra padding needed
Hematology	Increased hypercoagulability and risk of perioperative thromboembolic events Preoperative polycythemia suggests prolonged sleep apnea
Musculoskeletal	Increased prevalence of osteoarthritis
Psychology/psychiatry	Depression, reduced self-esteem, social stigma

Figure 44.1. Effects of obesity, positioning, and anesthesia on lung volumes. FRC, functional residual capacity; CC, closing capacity; CV, closing volume; RV, residual volume. (From: Ranasinghe JS, Penning DH. Morbid Obesity. In: Suresh MS, Segal S, Preston RL, et al, eds. Shnider and Levinson’s Anesthesia for Obstetrics. 5^th Edition. Philadelphia: WK Health/Lippincott Williams & Wilkins, 2013:582.)

Obesity increases oxygen consumption and carbon dioxide production even at rest. This is because of the metabolic activity of excess fat and the increased workload on supportive tissues. The body attempts to meet these metabolic demands by increasing both cardiac output and alveolar ventilation. Basal metabolic activity is usually within normal limits in relationship to body surface area and normocapnia is usually maintained by an increase in minute ventilation. This requires increased oxygen consumption because most obese patients retain their normal response to hypoxemia and hypercapnia. Arterial oxygen tension in morbidly obese patients’ breathing room air is lower than that predicted for similarly aged nonobese subjects in both sitting and supine positions. Chronic hypoxemia may lead to polycythemia, pulmonary hypertension and cor pulmonale.

Obese patients often suffer from OSA characterized by periodic, partial, or complete obstruction of the upper airway during sleep. In obese patients, OSA is more likely to result from airway obstruction produced by excess soft tissue. However, centrally mediated forms of sleep apnea can also occur. Physiologic abnormalities resulting from OSA include hypoxemia, hypercapnia, pulmonary hypertension, systemic vasoconstriction, and secondary polycythemia (from recurrent hypoxemia). These result in an increased risk of ischemic heart disease and cerebrovascular disease. Right ventricular failure can occur from hypoxic pulmonary vasoconstriction. Respiratory acidosis is usually limited only to periods of sleep.

The “gold standard” diagnostic test for OSA is overnight polysomnography (OPS). The inconvenience, time, and expense of OPS lead to an unknown fraction of obese patients with suspicious but no formal diagnosis of OSA.²⁸ Suggestive signs to look for during the preoperative visit include witnessed episodes of apnea during sleep, BMI ≥35, neck circumference ≥16 in (≥40 cm), hyperinsulinemia, and elevated glycosylated hemoglobin. Symptoms of snoring, frequent arousals during sleep and daytime sleepiness, impaired concentration, memory problems, and morning headaches are common but not predictive.²⁹,³⁰ A thorough preoperative evaluation for possible OSA is recommended long enough before elective surgery to allow preparation of a perioperative management plan.³¹ Preoperative initiation of continuous positive airway pressure (CPAP), especially in severe OSA cases, should be considered.³¹ Patients with confirmed or suspected OSA are at high risk of presenting with a difficult airway and postoperative pulmonary complications, and should be managed accordingly.³²,³³

The obesity hypoventilation syndrome (OHS) or Pickwickian syndrome may result from long-term OSA and is seen in 5% to 10% of morbidly obese patients. The OHS is a combination of obesity and chronic hypoventilation that ultimately results in pulmonary hypertension and cor pulmonale.³⁴ The presence of both obesity (BMI >30 kg/m²) and awake arterial hypercapnia (PaCO₂ >45 mm Hg) in the absence of known causes of hypoventilation supports the diagnosis. Prolonged OSA also alters the control of breathing, leading to CNS-mediated apneic events. This increases reliance on hypoxic drive for ventilation. The main ventilatory impairment of OHS is alveolar hypoventilation independent of intrinsic lung disease. Other characteristics of OHS include daytime hypersomnolence, hypercapnia, hypoxemia, and polycythemia. Right ventricular failure eventually ensues. These patients also have an increased sensitivity to the respiratory depressant effects of general anesthetics.

Cardiovascular and Hematologic Systems

Total blood volume is increased in the obese individual; but on a volume-to-weight basis, it is less than in nonobese individuals (50 mL/kg compared with 70 mL/kg). Most of this extra volume is distributed in the adipose tissue. Renal and splanchnic blood flows are increased. Cardiac output increases with increasing weight by as much as 20 to 30 mL/kg of excess body fat because of ventricular dilation and increases in stroke volume. The resulting increased left ventricular wall stress leads to hypertrophy, reduced compliance, and impairment of left ventricular filling (diastolic dysfunction) with elevated left ventricular diastolic pressure, and pulmonary edema.³⁵ When left ventricular wall thickening fails to keep pace with dilation, systolic dysfunction (“obesity cardiomyopathy”) and eventual biventricular failure results (Fig. 44-2).
Obesity accelerates atherosclerosis. Symptoms such as angina or exertional dyspnea occur only occasionally because morbidly obese patients often have very limited mobility and may appear asymptomatic even when they have significant cardiovascular disease.

Figure 44.2. Interrelationship of cardiovascular and pulmonary sequelae of obesity. OSA, obstructive sleep apnea; OHS, obesity hypoventilation syndrome; LV, left ventricular; RV, right ventricular.

Blood flow to fat is 2 to 3 mL/100 g of tissue. An excess of fat requires an increase in cardiac output, to parallel an increase in oxygen consumption. This leads to a systemic arteriovenous oxygen difference that remains normal or slightly above normal. Intraoperative ventricular failure may occur from rapid intravenous fluid administration (indicating left ventricular diastolic dysfunction), the negative inotropism of anesthetic agents, or pulmonary hypertension precipitated by hypoxia or hypercapnia. Cardiac dysrhythmias may be precipitated by fatty infiltration of the conduction system, hypoxia, hypercapnia, electrolyte imbalance, coronary artery disease, increased circulating catecholamines, OSA, and myocardial hypertrophy. Frequent ECG findings seen in morbidly obese patients include low QRS voltage, multiple criteria for left ventricular hypertrophy (LVH) and left atrial enlargement, and T-wave flattening in the inferior and lateral leads.³⁶ In addition, there is a leftward shift of the P-wave, QRS complex, and T-wave axes, lengthening of the corrected QT interval, and prolongation of the QT interval. Substantial weight reduction reverses many of these ECG abnormalities.³⁷

Cardiac output rises faster in response to exercise in the morbidly obese and is often associated with a rise in left ventricular end-diastolic pressure and pulmonary capillary wedge pressure. Similar changes occur during the perioperative period, which should prompt a low threshold for performing detailed cardiac investigations. Many obese patients have mild-to-moderate hypertension, with a 3 to 4 mm Hg increase in systolic and a 2 mm Hg increase in diastolic arterial pressure for every 10 kg of weight gained. Normotensive obese patients have reduced systemic vascular resistance, which rises with the onset of hypertension. Their expanded blood volume causes an increased cardiac output with a lower calculated systemic vascular resistance for the same level of arterial blood pressure. The renin–angiotensin system plays a major role in the hypertension of obesity by increased circulating levels of angiotensinogen, aldosterone, and angiotensin-converting enzyme. As little as 5% reduction in body weight leads to a significant reduction in renin–angiotensin activity in both plasma and adipose tissue, contributing to a reduction in blood pressure.³⁸

Obese patients have a normal-to-increased level of sympathetic nervous system activity, which predisposes to insulin resistance, dyslipidemia, and hypertension.³⁵,³⁹ These obesity-induced comorbidities are responsible for the increased cardiovascular risk in obese patients.⁴⁰,⁴¹ Insulin resistance enhances the pressor activity of norepinephrine and angiotensin II. Hyperinsulinemia further activates the sympathetic nervous system, causing sodium retention and contributes to obesity-induced hypertension. Hypertension causes concentric hypertrophy of the ventricle in normal-weight individuals but causes eccentric dilation in obese individuals. It is associated with increased preload and stroke work. The combination of obesity and hypertension causes left ventricular wall thickening and a larger heart volume; therefore, there is increased likelihood of cardiac failure (Fig. 44-3).

Obese individuals are also prone to cardiovascular disease because adipose tissue releases a large number of bioactive mediators. These can result in abnormal lipids, insulin resistance, inflammation, and coagulopathies.⁴⁰,⁴¹ Obese individuals have higher levels of fibrinogen (a marker for the inflammatory process of atherosclerosis), factor VII, factor VIII, von Willebrand factor, and plasminogen activator inhibitor-1 (PAI-1). Increased levels of fibrinogen, factor VII, factor VIII, and hypofibrinolysis are associated with hypercoagulability. High factor VIII levels are associated with increased cardiovascular mortality. Increased fasting triglyceride levels correlate with increased factor VII concentrations, and postprandial lipemia causes activation of factor VII. Endothelial dysfunction induced by insulin increases von Willebrand factor and factor VIII levels, predisposing to fibrin formation. Increased secretion of PAI-1 inhibits the fibrinolytic system and is associated with visceral obesity.⁴²

Gastrointestinal System

Gastric volume and acidity are increased, hepatic function is altered, and drug metabolism is adversely affected by obesity. Many fasting morbidly obese patients who present for elective surgery have gastric volumes in excess of 25 mL and gastric fluid pH <2.5 (the generally accepted volume and pH indicative of high risk for pneumonitis should regurgitation and aspiration occur). Delayed gastric emptying occurs because of increased abdominal mass that causes antral distension, gastrin release, and a decrease in pH with parietal cell secretion.⁴³,⁴⁴ Abdominal obesity increases intragastric pressure, increasing the frequency of transient lower esophageal sphincter relaxation, and/or hiatal hernia formation. An increase of >3.5 kg/m² in BMI is associated with a 2.7-fold increase in risk for developing new reflux symptoms.⁴³ An increased incidence of hiatal hernia and gastroesophageal reflux further increase aspiration risk.

Gastric emptying is faster with high-energy content intake such as fat emulsions, but because of larger gastric volume (up to 75% larger), the residual volume is increased. The combination of hiatal hernia, gastroesophageal reflux, and delayed gastric emptying, coupled with increased intra-abdominal pressure and high volume/low pH gastric content, puts the obese patient at risk for an increased incidence of severe pneumonitis should aspiration occur. Unpremedicated, nondiabetic fasting obese surgical patients who are free from significant gastroesophageal pathology are unlikely to have high volume, low pH gastric contents after routine preoperative fasting.⁴⁵ They should follow the same fasting guidelines as nonobese patients and be allowed to drink clear liquids up until 2 hours before elective surgery.⁴⁶ Weight loss significantly improves gastroesophageal reflux symptoms.⁴⁷

Peculiar morphologic and biochemical abnormalities of the liver are associated with obesity and include fatty infiltration (high prevalence of nonalcoholic fatty liver disease or NAFLD), inflammation (nonalcoholic steatohepatitis or NASH), focal necrosis, and cirrhosis. Fatty infiltration reflects the duration rather than the degree of obesity. Histologic and liver function test abnormalities are relatively common, but clearance usually is not reduced. Abnormal liver function tests are seen in up to one-third of obese patients who have no evidence of concomitant liver disease. The most common abnormality is an increased ALT. Despite these histologic and enzymatic changes, no clear correlation exists between liver function abnormalities and the capacity of the liver to metabolize drugs.⁴⁸ Morbidly obese patients who have undergone intestinal bypass surgery have a particularly high prevalence of hepatic dysfunction and cholelithiasis. This is also common in the general obese population due to abnormal cholesterol metabolism. The high prevalence of NAFLD, NASH, and cirrhosis necessitates careful assessment for pre-existing liver disease in obese patients scheduled for surgery. Features suggestive of NASH include hepatomegaly, elevated liver enzymes, and abnormal liver histology (steatosis, steatohepatitis, fibrosis, and cirrhosis).⁴⁰

Figure 44.3. Adaptation of the heart to obesity and hypertension. (Reprinted from: Messerli FH. Cardiovascular effects of obesity and hypertension. Lancet. 1982;1:1165, with permission.)

Renal and Endocrine Systems

Impaired glucose tolerance in the morbidly obese is reflected by a high prevalence of type II diabetes mellitus as a result of resistance of peripheral adipose tissue to insulin.³⁵ Many obese patients have an abnormal glucose tolerance test, and the relative risk of developing diabetes increases by 25% for every 1 kg/m² increase in BMI above 22 kg/m².³⁵ Hyperglycemia, insulin resistance, and diabetes predispose obese patients to wound infections and an increased risk of myocardial infarction. Exogenous insulin may be required perioperatively even in obese patients with type II diabetes mellitus to oppose the catabolic response to surgery. In addition to these concerns, subclinical hypothyroidism occurs in about 25% of all morbidly obese patients. Thyroid-stimulating hormone levels are frequently elevated, suggesting the possibility that obesity leads to a state of thyroid hormone resistance in peripheral tissues. Hypothyroidism may be associated with hypoglycemia, hyponatremia, and impaired hepatic drug metabolism.

Obesity is associated with glomerular hyperfiltration as evidenced by increased renal blood flow and an increased glomerular filtration rate. Excessive weight gain increases renal tubular reabsorption and impairs natriuresis through activation of the sympathetic and renin–angiotensin systems as well as physical compression of the kidney. With prolonged obesity, there may be a loss of nephron function, with further impairment of natriuresis and further increases in arterial pressure. Obesity-related glomerular hyperfiltration decreases after weight loss, which decreases the incidence of overt glomerulopathy.⁴⁹

Metabolic Syndrome

The metabolic syndrome, sometimes referred to as syndrome X and insulin resistance syndrome, is a cluster of metabolic abnormalities associated with an increased risk of diabetes and cardiovascular events. Individuals with this syndrome have up to a fivefold greater risk of developing type 2 diabetes mellitus (if not already present) and are also twice as likely to die from a myocardial infarction or stroke compared with those without the syndrome.⁵⁰ There are several diagnostic guidelines for metabolic syndrome.⁵¹ The most widely used is the one delineated by the revised 2004 National Cholesterol Education Program and the American Heart Association (NCEP II/AHA),⁵² which defines metabolic syndrome when three out of the following five conditions exist: (1) central obesity: Waist circumference ≥102 cm (≥40 in) in males, ≥88 cm (≥35 in) in females; (2) dyslipidemia: Triglycerides ≥150 mg/dL; (3) dyslipidemia: HDL ≤40 mg/dL in males, ≤50 mg/dL in females; (4) hypertension: ≥130/85 mm Hg
or use of antihypertensives; (5) elevated fasting glucose: ≥100 mg/dL (≥5.6 mmol/L) or use of medication for hyperglycemia. Weight loss and lifestyle changes, such as following a Mediterranean diet with high intake of fruits, vegetables, and fiber, improve the metabolic syndrome features.⁵⁰,⁵³

Pharmacology

Pharmacologic Principles

General pharmacokinetic principles dictate, with certain exceptions, that drug dosing should take into consideration the volume of distribution (V_D) for administration of the loading dose, and the clearance for the maintenance dose.⁵⁴ A drug that is mainly distributed to lean tissues should have the loading dose calculated on the basis of LBW. If the drug is equally distributed between adipose and lean tissues, dosing should be calculated on the basis of TBW. For maintenance, a drug with similar clearance values in both obese and nonobese individuals should have the maintenance dose calculated on the basis of LBW. However, a drug whose clearance increases with obesity should have the maintenance dose calculated according to TBW.

The relative volume of the central compartment in which drugs are first distributed remains unchanged in obese patients, but absolute body water content is decreased. Lean body and adipose tissue mass are increased, affecting lipophilic and polar drug distribution (Fig. 44-4). The V_D in obese patients is affected by multiple factors including reduced total body water, increased total body fat, increased lean body mass, altered protein binding, increased blood volume, increased cardiac output, increased blood concentrations of free fatty acids, triglycerides, cholesterol, and α₁-acid glycoprotein, lipophilicity of the drug, and organomegaly.⁶ Increased redistribution of a drug prolongs its elimination half-life even when clearance is unchanged or increased. Hyperlipidemia and an increased concentration of α₁-acid glycoprotein may affect protein binding, leading to a reduction in free drug concentration. Plasma albumin and total plasma protein concentrations and binding are not significantly changed by obesity, but when compared with normal-weight individuals, a relative increase in plasma protein binding may be evident. Splanchnic blood flow, blood volume, and cardiac output are all increased in obese patients. In contrast to the expected decrease in bioavailability of orally administered medications because of increased splanchnic blood flow, there is no significant difference in absorption and bioavailability when comparing obese and normal-weight subjects. Drugs that undergo phase I metabolism (oxidation, reduction, hydrolysis) are generally unaffected by changes induced by obesity, whereas phase II reactions (glucuronidation, sulfation) are enhanced.⁶

Figure 44.4. Body composition in extremely obese and weight-reduced states compared with reference female values. ICW, intracellular water; ECW, extracellular water. (Reprinted from: Das SK, Roberts SB, Kehayias JJ, et al. Body composition methods in extreme obesity. Am J Physiol Endocrinol Metab. 2003;284:E1080, with permission.)

Histologic abnormalities of the liver are common in the obese, with concomitant deranged liver function tests, but drug clearance is not usually affected. Renal clearance of drugs is increased in obesity because of increased renal blood flow and glomerular filtration rate.⁴⁹,⁵⁵ As a result of the increases in glomerular filtration rate and tubular secretion, drugs such as cimetidine and aminoglycoside antibiotics that depend on renal excretion may require increased dosing. Highly lipophilic substances such as barbiturates and benzodiazepines show significant increases in V_D for obese individuals.⁶ These drugs have a more selective distribution to fat stores and therefore a longer elimination half-life but with comparable clearance values to normal individuals. Less lipophilic compounds have little or no change in V_D with obesity. Exceptions to this rule include the highly lipophilic drugs digoxin, procainamide, and remifentanil.⁵⁶,⁵⁷,⁵⁸ Drugs with weak or moderate lipophilicity may be dosed on the basis of LBW. Adding 20% to the estimated IBW dose of hydrophilic medications is sufficient to include the obese patient’s extra lean mass. Nondepolarizing muscle relaxants can be dosed in this manner.

Increased blood volume in the obese patient decreases plasma concentrations of rapidly injected intravenous drugs. Fat, however, has poor blood flow, and doses calculated on actual body weight could lead to excessive plasma concentrations. Calculating initial doses based on LBW with subsequent doses determined by pharmacologic response to the initial dose is a reasonable approach. Repeated injections may accumulate in fat, leading to a prolonged response because of subsequent release from this large depot.

Specific Drugs

Patients’ usual medications should be continued until the time of surgery, with the possible exception of certain antihypertensives, insulin, and oral hypoglycemics. Antibiotic prophylaxis is usually indicated because of an increased incidence of wound infections in the obese.⁵⁹ Anxiolysis and prophylaxis against both aspiration pneumonitis and deep vein thrombosis (DVT) should be addressed preoperatively. Oral benzodiazepines are reliable for anxiolysis and sedation. Intravenous midazolam can also be titrated in small doses for anxiolysis during the immediate preoperative period. Dexmedetomidine, because of its minimal respiratory depressant effects, should be considered. Pharmacologic intervention with H₂-receptor antagonists, nonparticulate antacids, or proton pump inhibitors will reduce gastric volume, acidity, or both, thereby reducing the risk and severity of aspiration pneumonitis. Guidelines for dosing of common intravenous drugs utilized during anesthesia are presented in Table 44-3.

Table 44-3. Intravenous Drug Dosing in Obesity

Drug	Dosing	Practical Anesthesia Key Points
Thiopental	Induction: LBW (somewhat increased dose)	Increased initial dose due to increased blood volume, CO, muscle mass Rapid distribution from plasma to periphery Increased absolute dose Prolonged duration of action due to high lipophilicity and increased VD Longer elimination half-life
Propofol	Induction: LBW (somewhat increased dose) Maintenance infusion: TBW	Short duration of action due to rapid redistribution Highly lipophilic Cardiac output is major determinant of peak plasma concentration⁶⁰ Increased VD at steady state and increased clearance prevent increases in elimination half-life Total clearance and VD at steady state correlate with body weight during maintenance infusion Negative cardiovascular effects High affinity for fat and well-perfused organs High hepatic extraction and conjugation relate to TBW⁶¹
Succinylcholine	TBW	Pseudocholinesterase activity increases linearly with increasing weight and large extracellular fluid compartment Dose of succinylcholine should be increased
Rocuronium	LBW	Dosing according to LBW to prevent delayed recovery due to increased VD Faster onset and longer duration when dosed according to TBW^62,63 Pharmacokinetics and pharmacodynamics not altered in obese female patients
Vecuronium	LBW	Prolonged action when dosed according to TBW Dosing according to LBW to prevent delayed recovery due to increased VD and impaired hepatic clearance Obesity does not alter distribution or elimination of the drug
Atracurium	LBW	V_D, absolute clearance, and elimination half-life unchanged by obesity Unchanged dose per unit body weight without prolongation of recovery because of organ function-independent elimination⁶⁴
Cisatracurium	LBW	Pharmacokinetics similar to atracurium but prolonged duration of action when dosed according to TBW⁶⁵
Benzodiazepines	LBW	Highly lipophilic drugs with larger VD in obese patients result in longer duration of action Midazolam has potential for prolonged sedation because larger initial doses are required to achieve adequate serum concentrations
Fentanyl	LBW	Measured total body clearance has a nonlinear relationship to TBW and overestimates plasma concentration Fentanyl dosing based on a derived LBW or “pharmacokinetic mass” model correlates better with clearance than TBW dosing^66,67 Dosing based on TBW overestimates dose requirements in the obese patient
Sufentanil	LBW	Highly lipid soluble Increased VD and prolonged elimination half-life, which correlates with degree of obesity Distributes extensively in excess body fat Similar pharmacokinetic parameters in obese and nonobese predict similar plasma concentrations Overestimation of plasma concentration occurs in the morbidly obese range (BMI >40 kg/m²)⁶⁷
Remifentanil	LBW	Pharmacokinetics similar in obese and nonobese patients (i.e., more closely related to lean body mass than LBW)⁵⁷ Systemic clearance and VD corrected per kilogram of TBW is significantly smaller in the obese patient. Consider age and lean body mass for dosing
Dexmedetomidine	TBW	Highly selective α₂-adrenergic agonist Sedative–hypnotic, anesthetic-sparing analgesic, sympatholytic properties Lacks significant effects on respiration Ideal analgesic adjuvant in the morbidly obese patient⁶⁸ As part of a balanced anesthetic, infusion rates of 0.2–0.7 μg/kg/hr produce clinically effective sedation with decreased analgesic and anesthetic requirements
Neostigmine	TBW	Prompt early reversal but delayed full recovery during neostigmine-induced reversal of vecuronium dosed according to TBW⁶³
Sugammadex	N/A	A modified γ-cyclodextrin compound that encapsulates rocuronium, (and other steroid-based neuromuscular blockers to a lesser extent) May prove invaluable for more rapid and complete neuromuscular blockade reversal in obese patients⁶⁹
LBW, lean body weight; VD, volume of distribution; TBW, total body weight; BMI, body mass index; N/A, not available. Adapted from: Ogunnaike BO, Jones SB, Jones DB, et al. Anesthetic considerations for bariatric surgery. Anesth Analg. 2002;95:1793.

Preoperative Evaluation

Airway

Preoperative airway assessment in obese patients is of paramount importance. In an analysis of closed malpractice claims in the United States related to airway management, obesity played a significant role in a large number of cases.⁷⁰ Anatomic changes associated with obesity that contribute to a potentially difficult airway include limited movement of the atlantoaxial joint and cervical spine by upper thoracic and low cervical fat pads; excessive tissue folds in the mouth and the pharynx; a short, thick neck; a thick submental fat pad; suprasternal, presternal, and posterior cervical fat; and large breasts in females. Excess pharyngeal tissue deposited in the lateral pharyngeal walls may not be noticed during routine airway examination. The history obtained from the patient and examination of previous records may help predict airway difficulties.

Obesity is an accepted risk factor for difficult mask ventilation and airway management. With adequate positioning and airway resources available, most obese patients can be adequately and safely managed. Overall, the magnitude of BMI by itself does not seem to have much influence on the difficulty of laryngoscopy.⁷¹ Such difficulty, in most studies, correlates with increased age, male sex, temporomandibular joint pathology, Mallampati classes 3 and 4, OSA, and abnormal upper teeth.⁷²,⁷³,⁷⁴ The predictive role of OSA per se on difficult intubation has been recently disputed.⁷⁵ In a prospective study in bariatric patients by Neligan et al.⁷⁵ only a Mallampati score ≥3 and male gender, but not BMI, OSA or the apnea–hypopnea index (AHI), predicted the risk of difficult intubation. The patient’s neck circumference has been identified as the single biggest predictor of problematic intubation in morbidly obese patients.⁷³ The probability of a problematic intubation is approximately 5% with a 40-cm neck circumference compared with a 35% probability at 60-cm neck circumference. In this study by Brodsky et al.,⁷³ a larger neck circumference was associated with male gender, a higher Mallampati score, laryngoscopy grade 3 views, and OSA.

Cardiopulmonary Systems

As stated above, when evaluating the obese patient preoperatively, a review of previous anesthetic experiences, as detailed by the patient, and previous anesthetic records are useful and important. Because obese patients often have limited exercise tolerance they may appear asymptomatic even though they have significant cardiovascular disease. Obese patients should be evaluated for systemic hypertension, pulmonary hypertension, signs of right and/or left ventricular failure, and ischemic heart disease. Signs of cardiac failure such as elevated jugular venous pressure, pathologic heart sounds, pulmonary crackles, hepatomegaly, and peripheral edema may all be difficult to detect because of excess adiposity. Pulmonary hypertension is fairly common in this patient population because of the chronic pulmonary impairment. The common features of pulmonary hypertension are exertional dyspnea, fatigue, and syncope (which reflect an inability to increase cardiac output during activity). Tricuspid regurgitation on echocardiography is the most useful confirmatory test of pulmonary hypertension but should be combined with clinical evaluation. An ECG may demonstrate signs of right ventricular hypertrophy such as tall precordial R waves, right axis deviation, and right ventricular strain. The higher the pulmonary artery pressure the more sensitive the ECG. Chest radiographs may show evidence of underlying lung disease and prominent pulmonary arteries.⁷⁶

Evidence of sleep apnea and the obstructive hypoventilation syndrome should be obtained preoperatively not only because patients with these syndromes may present with difficult airway management issues, but also because the conditions are associated with increased perioperative pulmonary complications. A history of hypertension or a neck circumference >40 cm correlates with an increased probability of OSA. OSA is a legitimate reason to delay surgery for a proper workup.⁷⁷ OSA patients should generally be treated as inpatients; however, outpatient surgery can be considered under certain circumstances, including mild OSA, use of local or regional anesthesia with minimal sedation, availability of a 23-hour observation postanesthesia care unit, and when patients can resume oral medication at the time of discharge. OSA patients on a CPAP device at home should be instructed to bring it with them to the hospital as it may be needed postoperatively. The possibility of invasive monitoring, prolonged intubation, and postoperative mechanical ventilation should be discussed with obese patients. Arterial blood gas measurements help evaluate ventilation, as well as the need for perioperative oxygen administration and postoperative ventilation. Routine pulmonary function tests and liver function tests are not cost-effective in asymptomatic obese patients.

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