Introduction

Glucocorticoids were introduced into clinical practice in 1949 with the release of a purified preparation known as cortisone. The treatment was revolutionary for patients with primary adrenal insufficiency (AI) and for the management of other acute and chronic diseases such as rheumatoid arthritis and systemic lupus erythematous. Shortly after the introduction of cortisone, two case reports were published describing surgical patients receiving long-term glucocorticoid treatment whose treatment was held in the perioperative period. The first involved a 34-year-old man who had cortisone therapy (25 mg twice daily) discontinued 48 hours before surgery. His subsequent death was attributed to acute AI caused by abrupt withdrawal of glucocorticoids. However, extenuating circumstances may have contributed to his death. The second case involved a 20-year-old woman who had been taking 62.5 to 100 mg of cortisone daily for approximately 4 months. She died less than 6 hours after surgery; autopsy findings confirmed bilateral adrenal hemorrhages and cortical atrophy indicative of AI. From these case reports came the conventional wisdom to supplement patients receiving exogenous steroids with large “stress doses” throughout the perioperative period. This practice came under scrutiny because of questions about efficacy and concern about side effects from excessive doses.

Endogenous glucocorticoids are cholesterol derivatives produced in the zona fasciculata of the adrenal cortex. Their release is controlled by a feedback mechanism known as the hypothalamic–pituitary–adrenal (HPA) axis ( Figure 26-1 ). Corticotropin-releasing hormone (CRH), released by the hypothalamus, acts on the anterior pituitary gland to initiate the production of adrenocorticotropic hormone (ACTH or corticotropin). ACTH then stimulates the adrenal glands to produce cortisol, which acts as negative feedback for CRH in the hypothalamus. Intracellular glucocorticoid receptors known as NR3C1 are ubiquitous, and glucocorticoids are integral factors in modulating normal cellular homeostasis and metabolism. Cortisol potentiates production of catecholamines and regulates the synthesis, responsiveness, coupling, and regulation of beta-adrenergic receptors. Glucocorticoids also regulate the normal metabolism of carbohydrates, proteins, and lipids. Glucocorticoid hormones modulate cardiovascular function and wound healing and have numerous other important metabolic functions.

The Hypothalamic–Pituitary–Adrenal Axis. Plus signs indicate stimulation, and minus signs indicate inhibition. ACTH, adrenocorticotropic hormone (corticotrophin); CRF, corticotropin-releasing factor.

Daily endogenous glucocorticoid secretion is estimated to be between 5 and 10 mg/m ² . This corresponds to 5 to 7 mg/day of oral prednisone or 20 to 30 mg/day of hydrocortisone. Cortisol synthesis can increase under conditions of stress to 100 mg/m ² /day.

Deficiencies of glucocorticoid production result in AI, which can be classified as a primary, secondary, or tertiary process with acute and chronic forms ( Table 26-1 ). Primary AI occurs in patients who have destruction of more than 90% of the adrenal glands by hemorrhage, tumor, infection, or an inflammatory process. This results in deficient production of both mineralocorticoids and glucocorticoids. Primary AI is relatively rare, most often resulting from autoimmune destruction of the adrenal glands. In developing regions of the world, it is most commonly due to tuberculous destruction of the adrenals. Patients with primary AI always require steroid replacement/supplementation with a medication(s) that include glucocorticoid and mineralocorticoid effects. Secondary AI is also relatively uncommon and results from insufficient production of ACTH resulting from destruction or dysfunction of the hypothalamus or pituitary gland. Patients with secondary AI typically require only glucocorticoid replacement and not mineralocorticoid replacement because mineralocorticoid activity is regulated primarily through the renin–angiotensin system and remains intact.

Tertiary, or iatrogenic, AI is the most commonly encountered type. Tertiary AI results from the suppression of the HPA axis over time, as a result of the administration of exogenous glucocorticoids. Long-term ACTH suppression from steroid treatment leads to adrenal atrophy. This can result in a potentially harmful situation if exogenous glucocorticoids are discontinued because the adrenals can no longer produce adequate cortisol.

Normal Response to Surgical Stress

Salem and colleagues reviewed seven prospective analyses performed between 1957 and 1975 examining cortisol secretion after major surgery. Combined, the total number of subjects in these investigations was only 40. None of the patients examined were known to be adrenally insufficient or taking glucocorticoids. The reported range of 24-hour cortisol secretion was wide, varying from 60 mg/24 hr to 310 mg/24 hr. In 1972 Wise and colleagues reported 24-hour postoperative cortisol secretion to be 60 mg. The following year, Kehlet and Binder reported an immediate postoperative cortisol secretion rate of 10 mg/hr, which decreased to 5 mg/hr 24 hours after surgery. It is generally accepted, however, that most healthy, non–steroid-dependent patients will secrete somewhere between 75 and 150 mg of cortisol in the first 24 hours after major surgery or up to 100 mg/m ² .

Integrity of the Hypothalamic–pituitary–adrenal Axis in Patients Taking Long-Term Steroids

Several studies have confirmed that patients taking small doses of steroids (≤5 mg of prednisone or its equivalent per day) retain normal HPA function. In 1973 Kehlet and Binder performed a prospective case-control study to determine whether patients receiving long-term glucocorticoid therapy could mount a physiologic response to major surgery if steroids were discontinued perioperatively. With 14 non–steroid-dependent surgical patients serving as control subjects, they prospectively followed up 74 patients on long-term glucocorticoid therapy undergoing major surgery (prednisone dose, 5 to 80 mg/day) and 30 steroid-dependent patients undergoing minor surgery (prednisone dose, 5 to 30 mg/day). Glucocorticoids were stopped 36 hours preoperatively and restarted 24 hours postoperatively. Plasma cortisol levels were measured for the first 24 hours postoperatively. Approximately 30% of the glucocorticoid-treated patients exhibited a blunted adrenocortical response to surgery, but only one patient showed any clinical signs or symptoms of AI. Interestingly, the majority of the control subjects in the minor surgery category showed little or no cortisol response to surgery. The authors concluded that subnormal adrenal stress responses were more prevalent in patients maintained on steroids at either higher doses or longer durations. Patients who received more than 12.5 mg of prednisone for more than 6 months, more than 10 mg of prednisone for more than 2 years, or more than 7.5 mg of prednisone for more than 5 years all showed an impaired adrenocortical response. The one patient who was symptomatic had no detectable plasma cortisol but was treated without resultant morbidity. Based on this report it has been hypothesized that the dose and the duration of steroid therapy influence cortisol response to stress.

In 50 patients receiving long-term low-dose prednisone (<10 mg/day for a mean duration of 41 months), La Rochelle and colleagues observed that all the patients receiving 5 mg/day or less had a normal response to a standard-dose rapid cosyntropin stimulation test. Those receiving 5.5 to 6.8 mg/day displayed an intermediate response, and those with mean doses greater than 6.8 mg/day displayed a suppressed response to ACTH stimulation.

Subsequently, Friedman and colleagues prospectively evaluated 28 patients receiving long-term glucocorticoid therapy undergoing major orthopedic surgeries. The mean duration and dose of prednisone therapy before surgery in this group was 7 years and 10 mg/day, respectively. Although patients were administered their baseline therapy up to the time of surgery, perioperative stress doses of steroids were not given. Despite this omission, no hemodynamic or biochemical changes consistent with perioperative glucocorticoid deficiency were observed.

Kenyon and Albertson performed a prospective study on 40 patients taking prednisone (doses from 5 to 10 mg/day) who were admitted to the hospital for illness, metabolic abnormalities, or surgery. No stress-dose steroids were given at any time during hospitalization. Over the first 36 hours, the authors measured serum cortisol, 24-hour urine cortisol, and ACTH levels. Once the patients’ clinical condition improved, a cosyntropin stimulation test (250 µg) was repeated. Although the response to the cosyntropin stimulation test was blunted in 63% of the subjects, 97% had normal or increased urinary cortisol concentrations. This implies that despite long-term steroid treatment, adrenal function and endogenous glucocorticoid production were sufficient to meet the stress of illness or surgery.

Evidence That Surgery-Induced Acute Adrenal Insufficiency is Harmful

The case reports from Fraser et al and Lewis et al were sufficient to convince the medical community that acute AI from perioperative glucocorticoid withdrawal had the potential to cause serious morbidity and mortality risks. In 1976 Kehlet produced an extensive review of 57 case reports from 1952 to 1973 documenting perioperative shock or death in patients taking glucocorticoids. In all cases, adverse outcomes were suspected to be secondary to stress-induced AI. The interval between surgery and shock or death ranged from preoperatively to 48 hours postoperatively. Interestingly, only 3 cases of the 57 displayed hypotension and low plasma cortisol levels, suggesting acute AI. The remainder of the cases were inconclusive or had no evidence to link the outcomes to AI.

In contrast, two large studies support the rarity of acute AI secondary to inadequate perioperative glucocorticoid coverage. Mohler and colleagues performed a retrospective review of 6947 urologic procedures in glucocorticoid-treated patients. Only one case of perioperative AI was identified (0.01% of patients). Alford and colleagues performed a similar review of 4346 cardiothoracic surgeries and confirmed only five cases of AI (0.1% of patients). These reviews support the fact that surgically induced AI can occur, although it is a relatively rare occurrence.

One group of patients that may deserve special consideration is elderly surgical patients. To determine the incidence and outcome of AI in elderly patients having high-risk surgery, Rivers and colleagues performed a prospective, observational case study. A total of 104 consecutive adult patients (excluding patients with a history of steroid use, known adrenal dysfunction, and those administered etomidate) who required vasopressor therapy postoperatively despite adequate volume resuscitation received a cosyntropin (synthetic ACTH) stimulation test with plasma cortisol measurements at 30 and 60 minutes. Empiric hydrocortisone (100 mg intravenously [IV] for three doses) was given at the discretion of the primary team. Adrenal dysfunction (defined as a serum cortisol concentration less than 20 mg/dL with a change in cortisol concentration of less than 9 mg/dL after ACTH) or functional hypoadrenalism (serum cortisol concentration less than 30 mg/dL with a change in cortisol concentration of less than 9 mg/dL after ACTH) was found in 32.7% of patients. The mortality rate was significantly lower in the hydrocortisone-treated patients with AI (21% versus 45%, p < 0.01). This incidence of relative AI is higher than would be expected for both the general surgical population and for those receiving long-term steroid treatment.

Evidence for Perioperative Steroid Replacement

Most of the clinical data on adrenal replacement therapy in the perioperative period are based on case series or drawn from clinical experience. There are few well-designed, prospective, randomized, blinded clinical trials investigating optimal perioperative steroid supplementation. Nonetheless, because of the potential for morbidity and mortality related to acute AI, it is generally agreed that certain patient populations should receive empiric perioperative steroid supplementation. The difficulty lies in determining the dose and duration of treatment.

For many years, all surgical patients taking glucocorticoids were given a standardized dose of supplementary steroid throughout the perioperative period. This method eventually came under question because of the deleterious effects of large doses of steroids, including poor wound healing, inadequate glucose control, fluid retention, hypertension, electrolyte imbalances, immunosuppression, gastrointestinal bleeding, and untoward psychological effects.

In 1975, Kehlet suggested that procedures be divided into “major” and “minor” categories. For major surgeries (e.g., intrathoracic, major vascular, or major abdominal operations), the recommendation was for 25 mg IV hydrocortisone at induction, followed by 100 mg IV hydrocortisone every 24 hours until the patient was able to resume oral steroid therapy. The goal of this approach was to adequately replace the increased cortisol requirements of 75 to 150 mg in the first 24 hours. For minor surgeries (surgeries taking less than 1 hour and those performed under local anesthetic), Kehlet suggested 25 mg IV hydrocortisone at the start of surgery and the resumption of oral therapy postoperatively. This recommendation was based on a study showing that healthy subjects often do not mount a stress response to minor surgery and, at most, secrete 50 mg/day of cortisol.

In 1978, Gran and Pahle recommended depot-betamethasone acetate/phosphate as a single intramuscular (IM) injection in perioperative patients receiving glucocorticoids. In a prospective cohort study on 1461 surgical patients receiving long-term steroid therapy, patients were given depot-betamethasone before surgery: 2 mg for major procedures and 1 mg for minor procedures. There were no reports of AI, delayed healing, or gastrointestinal bleeding. The authors contend that ease of administration is a major benefit of this regimen.

Salem and colleagues advised that perioperative supplementation should be individualized and based on prior steroid dose, duration, and degree of anticipated surgical stress. For minor surgeries, 25 mg hydrocortisone or an equivalent dose (oral prednisone or a parenteral equivalent) was suggested, and the long-term dose should be resumed the day after surgery. For procedures of perceived moderate stress, such as an open cholecystectomy or segmental colon resection, 50 to 75 mg/day of hydrocortisone or an equivalent dose (oral or parenteral) with a rapid taper over 1 to 2 days was recommended. For major surgery, such as cardiac surgery involving bypass, a target of 100 to 150 mg of hydrocortisone (or equivalent) per day with a rapid taper over 2 to 3 days was advised (see Table 26-3 later in this chapter).

Most recently, Zaghiyan et al reported no significant benefit to perioperative glucocorticoid administration (100 mg hydrocortisone IV at the time of surgery, then 100 mg hydrocortisone every 8 hours for 24 hours, then 20 mg oral prednisone tapered over 3 days) compared with no perioperative steroids among patients with inflammatory bowel disease who had received corticosteroids any time during the year preceding colon surgery. None of the patients was receiving steroids at the time of surgery. Thirty-eight patients underwent 49 surgical procedures. Perioperative glucocorticoids were administered and not administered for 11 and 38 procedures, respectively. No differences in postoperative surgical morbidity or mortality were identified between groups, although the group receiving steroid treatment had more tachycardia.

Areas of Evolving Interest and Ongoing Controversy

There are several areas of specific interest in the therapeutic administration of glucocorticoids in critically ill patients. These include treatment of patients with severe sepsis and septic shock, acute respiratory distress syndrome (ARDS), community-acquired pneumonia (CAP), meningitis, traumatic brain injury (TBI), and acute spinal cord injury (SCI). The use of etomidate in critically ill patients, a topic of renewed interest, is also reviewed.