Hypotension and adrenal insufficiency.

This case conference describes two patients with hypotension who eventually were diagnosed with adrenal insufficiency. The first patient was initially believed to have a cardiac abnormality and the second patient sepsis, which was causing the continued hypotension. Both patients exhibited several clinical similarities; however, neither had the classic symptoms of adrenal insufficiency. This report discusses the causes of postoperative hypotension, diagnostic testing, and treatment for patients with adrenal insufficiency, and briefly reviews the literature.

Variables affecting outcome in critically ill patients.

Critical care medicine has evolved as a field of science and clinical care. Despite important contributions to our understanding of the molecular basis of critical illness, we still remain troubled by our lack of insight into why some patients have favorable outcomes from critical illness and others do not. This article explores the hypothesis that at least five important variables may alter the outcome of patients suffering from a variety of critical illnesses. These variables include the premorbid immune or genetic status of the patient, the patient's gender, the circulating cholesterol concentration, the patient's age, and various iatrogenic and nosocomial events. Insights into the importance of these five variables may provide opportunities for physicians and scientists to improve outcome in patients suffering from critical illness. Clearly, altering iatrogenic and nosocomial events is already within the realm of opportunity.

The laboratory-clinical interface: point-of-care testing.

POC testing provides an opportunity for clinicians and laboratorians to work together to consider how best to serve the patients within an individual institution. Each health system has unique characteristics relative to patient population, as well as a unique laboratory structure. If physicians, nurses, laboratorians, and pathologists work collaboratively, the best interests of patients will be served. In some institutions that cater to specific patient groups, POC testing may offer clear and distinct advantages. In other institutions with sophisticated transport systems and established rapid response capabilities, the quality resulting from central laboratory testing may outweigh any advantages of bedside testing. Clearly, attention to regulatory issues, QC issues, the importance of proper documentation, proficiency testing, performance enhancement, and cost-effectiveness is requisite. As the technology for diagnostic testing advances through more microcomputerization, microchemistry, and enhanced test menus, the concept of POC testing will need perpetual revisiting. We hope that the information provided here will aid clinicians, laboratorians, and administrators in their quest to best serve their patients.

Use of different anticoagulants in test tubes for analysis of blood lactate concentrations: Part 2. Implications for the proper handling of blood specimens obtained from critically ill patients.

OBJECTIVES: a) To test the hypothesis that the measurement of the circulating lactate concentration is influenced by the anticoagulant in the test tube that contains the blood sample; b) to test the hypothesis that the measurement of the circulating lactate concentration is influenced by the tissue used for analysis. DESIGN: A prospective, controlled study. SETTING: A critical care research laboratory, a 20-bed intensive care unit (ICU), and the general wards. SUBJECTS: Twenty-three ICU and ward patients with hyperlactatemia and 19 healthy volunteers. INTERVENTIONS: Blood samples were collected for determination of blood lactate concentration. MEASUREMENTS AND MAIN RESULTS: Venous blood samples (12 mL) were obtained from each of the 19 normal subjects and each 12-mL specimen was evenly divided into six aliquot portions (six test tubes). Experiment 1: Of the six tubes, two tubes were set aside for experiment 2. The other four tubes were used to test four anticoagulants (one anticoagulant per tube). The anticoagulants tested were: sodium heparin; EDTA; lithium heparin; and sodium citrate. Lactate concentrations were analyzed using an ion-selective, amperometric electrode that we have previously validated. There were no statistically significant differences between the lactate concentrations derived from blood samples stored in sodium heparin, EDTA, or lithium heparin (p > .05; n = 19; Student-Newman-Keuls' multiple comparisons test). The lactate concentration of blood stored in sodium citrate, however, was lower than all other anticoagulants (p < .001; n = 19; Student-Newman-Keuls' multiple comparisons). Experiment 2: Of the remaining two test tube samples from each subject, one tube contained sodium heparin and the other tube did not contain an anticoagulant. Each of these two tubes was centrifuged at 50 degrees F (10 degrees C) for 15 mins to obtain plasma and serum samples. Lactate concentrations were measured in the serum and plasma and compared with those concentrations found in whole blood samples from the tube containing sodium heparin from experiment 1. The plasma and serum lactate concentrations were consistently higher than the whole blood lactate values from the same specimen (p < .05; n = 42; Student-Newman-Keuls' multiple comparisons test). Since experiment 1 involved the collection of blood from healthy volunteers with normal lactate concentrations, we chose to investigate whether this discordance between plasma or serum and whole blood was dependent on the lactate concentration. To answer this question, we studied 23 patients with known hyperlactatemia and found that in subjects with a lactate concentration of < 2.2 mmol/L, there was a difference of 0.11 mmol/L in the mean values between plasma and whole blood concentrations (p < .0004; n = 19; paired t-test). In subjects with a lactate concentration of > 2.2 mmol/L, there was a difference of 0.14 mmol/L (p < .0001; n = 23; paired t-test) in the mean values between plasma and whole blood. In all samples at all concentrations, there was no significant difference between serum vs. plasma samples (p > .05; Student-Newman-Keuls' test). CONCLUSIONS: a) Sodium citrate, as an anticoagulant, caused lower lactate concentrations to be measured as compared with heparin or EDTA; b) the measurement of lactate concentrations in plasma or serum samples yields a higher value than the concentration found in the original whole blood specimen.

Effects of crystalloid solutions on circulating lactate concentrations: Part 1. Implications for the proper handling of blood specimens obtained from critically ill patients.

OBJECTIVES: a) To test the hypothesis that circulating lactate concentrations are the same in simultaneously collected arterial and central venous blood specimens; b) to test the hypothesis that even small amounts of crystalloid solutions, which are inadequately "cleared" from these indwelling arterial and venous catheters, can lead to clinically important and misleading changes in the measured lactate values. DESIGN: A prospective, multiexperiment study. SETTING: A critical care research laboratory and a 20-bed intensive care unit (ICU). PATIENTS: Three hundred fifty-five patients. INTERVENTIONS: Blood samples were collected. MEASUREMENTS AND MAIN RESULTS: Experiment 1: Simultaneously collected arterial and central venous blood specimens were obtained on 148 occasions from 48 medical ICU patients receiving no lactated Ringer's solution (RL). Arterial and central venous lactate values were nearly identical in these patients. The correlation between the arterial and central venous lactate concentrations was excellent (r2 = .85; p < .0001) and the agreement between the arterial and central venous lactate concentrations was also excellent (bias and precision = 0.04 mmol/L and +/- 0.38 mmol/L, respectively). Experiment 2: Arterial and mixed venous blood samples were obtained from 100 percutaneous transluminal coronary angioplasty (PTCA) and 75 cardiac surgical patients immediately before the performance of these cardiac procedures. We found the central venous lactate concentrations to be higher than arterial lactate values in the cardiac surgical group, and there was a very poor correlation (r2 = .07) between arterial and central venous lactate values in the cardiac surgical group. The correlation between central venous and arterial lactate concentrations in the PTCA patients was excellent (r2 = .84) and similar to the findings of experiment 1. Since the cardiac surgical patients received RL and the PTCA patients received no RL, we speculated that the intravenous infusion of RL in the cardiac surgical group accounted for these discordant findings. To test this speculation, we performed experiments 3 and 4. Experiment 3: In a large bench study, blood specimens were divided into multiple 1-mL aliquot portions, to which 0.01, 0.05, 0.10, 0.50, or 1.0 mL of various crystalloid solutions, containing or not containing RL, were added. In a volume-dependent and linear manner, solutions containing RL increased the circulating lactate concentration from 10% to > 400% of the baseline lactate value. In a volume-dependent and linear fashion, the non-RL crystalloid solutions decreased the lactate concentration by 0 to 66% of the baseline nondiluted lactate concentration. Experiment 4: In 30 different cardiac surgical patients, we simultaneously obtained central venous and arterial blood specimens. Patients this time received no RL, and catheter lines were adequately cleared (removal > 5 mL) of crystalloid solutions. We found a correlation (r2 = .82; p < .0001) that was virtually identical to the findings of experiment 1 and to the findings in the PTCA group of experiment 2. CONCLUSIONS: a) Arterial and central venous lactate concentrations are similar in hemodynamically stable critically ill patients, b) Even small amounts of RL-containing solutions in catheters used for blood sampling may cause false increases in the circulating lactate concentration. c) Even small amounts of non-RL crystalloid solutions in catheters used for blood sampling may falsely decrease circulating lactate values. d) When blood specimens are drawn from indwelling catheters, all crystalloid solutions must be cleared from the line.

Effect of intravenous lactated Ringer's solution infusion on the circulating lactate concentration: Part 3. Results of a prospective, randomized, double-blind, placebo-controlled trial.

OBJECTIVES: We previously discovered that small amounts of lactated Ringer's solution, which are inadequately cleared from an intravenous catheter, falsely increase the circulating lactate concentration in blood samples collected from that catheter. That finding prompted us to test the hypothesis that intravenous lactated Ringer's solution, infused at a rate used in resuscitation, would increase the circulating lactate concentration. DESIGN: A prospective, randomized, double-blinded, placebo-controlled study. SETTING: A critical care research laboratory. SUBJECTS: Twenty-four normal, healthy, adult volunteer subjects. INTERVENTIONS: Two intravenous catheters were placed. One was used for the infusion of the test solution and the other catheter was used for blood sampling. Blood samples were serially collected for the determination of blood lactate concentrations. MEASUREMENTS AND MAIN RESULTS: Twenty-four healthy adult volunteers were randomized to receive a 1-hr infusion of either lactated Ringer's solution (n = 6), 0.9% saline (n = 6), 5% dextrose in lactated Ringer's solution (D5RL) (n = 6), or 5% dextrose in water (D5W) (n = 6). Each subject received nothing by mouth after midnight. At 0800 hrs, catheters were inserted and each subject received 1 L of the assigned solution over 1 hr. Throughout the study, the subjects were at rest. Three-milliliter samples of venous blood were collected before, during (at 15, 30, 45, and 60 mins), and after (at 90, 120, and 240 mins) the infusion. Blood samples were placed on ice immediately after collection and analyzed within 5 mins of collection. Lactate concentrations were determined using an ion-selective, amperometric electrode, which we have previously validated. Lactate concentrations were compared between subjects receiving lactated Ringer's solution vs. subjects receiving normal saline. A similar comparison was made between subjects receiving D5RL vs. D5W at similar time points during the study. There were no clinically or statistically significant differences in lactate values at the time points studied in those subjects receiving lactated Ringer's solution vs. those persons receiving normal saline (p > .05; n = 12; Student-Newman-Keuls' multiple comparison test) or those subjects receiving D5W vs. those subjects infused with D5RL (p > .05; n = 12; Student-Newman-Keuls' multiple comparison test). In no case did the circulating lactate values exceed 2 mmol/L (the upper limit of normal). CONCLUSIONS: The short-term infusion of lactated Ringer's solution in normal adults (hemodynamically stable) does not falsely increase circulating lactate concentrations when 1 L is given over 1 hr. Therefore, clinicians should not disregard increased lactate concentrations in patients receiving a rapid infusion of lactated Ringer's solution.

Blood conservation in acute care and critical care.

Blood conservation has evolved into an important issue in hospital-based medicine. Increased awareness of and worry about transfusion-associated diseases have prompted a focus on this important area. New technologies, including continuous intraarterial monitoring devices, microchemical technologies, new drug development (recombinant human erythropoietin and aprotinin) and intraoperative salvage techniques have made the concept of clinically important blood conservation possible. In this article, the authors review clinically important areas regarding blood conservation, which are subsequently detailed in this issue of AACN Clinical Issues. Emphasis is placed on the need for blood conservation in acute and critical care practice and the technologies available to achieve this goal.

Lack of effectiveness of magnesium in chronic stable asthma. A prospective, randomized, double-blind, placebo-controlled, crossover trial in normal subjects and in patients with chronic stable asthma.

BACKGROUND: Magnesium sulfate has been helpful in the treatment of acute exacerbations of asthma. We hypothesized that magnesium would also be an effective bronchodilator in patients with chronic stable asthma. METHODS: We performed a prospective, randomized, double-blind, placebo-controlled, crossover trial in 15 patients with chronic, stable asthma and 10 nonasthmatics. On study day 1, spirometry and albuterol challenge were used to confirm the presence of asthma according to American Thoracic Society criteria. On study day 2, subjects received intravenous magnesium sulfate (2 g) or placebo (saline). On study day 3, subjects were crossed over to receive the other drug. Spirometry was performed before, during, and after drug or placebo administration. Circulating ionized magnesium concentrations were determined before and after intravenous magnesium or placebo administration. RESULTS: Magnesium infusion caused no statistically significant changes in forced expiratory volume in 1 second (mean +/- SEM, 1.92 +/- 0.13 L before, 1.98 +/- 0.12 L during, and 2.01 +/- 0.14 L after magnesium administration), forced vital capacity (mean +/- SEM, 3.44 +/- 0.25 L before, 3.60 +/- 0.26 L during, and 3.59 +/- 0.25 L after magnesium administration), or maximum forced expiratory flow rate (mean +/- SEM, 5.42 +/- 0.44 L/second before, 5.46 +/- 0.46 L/second during, and 5.57 +/- 0.49 L/second after magnesium administration). Placebo caused no changes in these three physiologic variables. CONCLUSION: Magnesium is not effective as a bronchodilator in chronic, stable asthmatics or in normal non-asthmatic adults.

Relationship between blood lactate concentrations and ionized calcium, glucose, and acid-base status in critically ill and noncritically ill patients.

OBJECTIVE: To determine the relationships between circulating blood lactate concentrations and several biochemical variables including ionized calcium, glucose, pH, and acid-base status in critically ill and noncritically ill patients. DESIGN: A prospective, cohort study. SETTING: The critical care research laboratory, intensive care unit (ICU), emergency room (ER), and general ward of a 466 bed university-affiliated hospital. PATIENTS: Three-hundred thirty-four critically ill and noncritically ill patients. INTERVENTION: None. MEASUREMENTS AND MAIN RESULTS: Circulating blood lactate concentrations, ionized calcium concentrations, blood glucose, pH, and base deficit values were simultaneously determined in blood samples from various patient populations. Descriptive data and physiologic parameters were also recorded. Circulating lactate and ionized calcium determinations were performed simultaneously in 334 whole blood samples from 334 subjects. There was neither a statistically significant nor clinically relevant correlation between circulating lactate concentrations and ionized calcium concentrations when lactate values were < or = 2 mmol/L (p = 0.8962, r2 = .01) or when lactate values were > 2 mmol/L (p = .3697, r2 = .09) in a heterogeneous patient population. Our study populations included five subject groups: a) nonhypotensive ICU patients (n = 93), b) nonhypotensive ER patients (n = 85), c) nonhypotensive general ward patients (n = 44), d) hypotensive patients from the ICU, ER, and general wards (n = 39), and e) normal controls (n = 73). There was neither a statistically significant nor clinically relevant correlation between circulating lactate concentrations and ionized calcium concentrations in each of the five populations studied for lactate values either < or = 2 mmol/L or > 2 mmol/L. We studied the relationship between circulating lactate concentrations and blood glucose concentrations (n = 334 patients), arterial pH and base deficit (n = 163 patients), and venous pH and base deficit (n = 171 patients). Statistically significant, but perhaps not clinically relevant correlations were observed when comparing circulating lactate values with blood glucose values (p = .0330, r2 = .12), arterial pH (p = .0007, r2 = .26) and base deficit from arterial specimens (p = .0014, r2 = .25). There were neither statistically significant nor clinically relevant correlations when comparing circulating lactate concentrations with venous pH (p = .9098, r2 = .01) or base deficit determined from venous blood specimens (p = .1365, r2 = .11). CONCLUSIONS: a) There is neither a statistically significant nor clinically relevant relationship between whole blood lactate concentrations and ionized calcium concentrations when studying patients with or without hyperlactatemia. b) Although there is a statistically significant correlation between circulating lactate concentrations and blood glucose concentrations, arterial pH or arterial base deficit, such associations do not appear to be clinically important.

Progressive magnesium deficiency increases mortality from endotoxin challenge: protective effects of acute magnesium replacement therapy.

OBJECTIVES: To study the effects of endotoxin on magnesium homeostasis; to determine if progressive magnesium deficiency alters outcome from endotoxin challenge; and to evaluate the efficacy of magnesium therapy in reducing endotoxin-induced mortality. DESIGN: Prospective, placebo-controlled, randomized, multiexperiment studies. SETTING: Research laboratory of a university hospital. SUBJECTS: Male Sprague Dawley rats (n = 299). INTERVENTIONS: Experiment 1 was designed to test if endotoxin alters magnesium homeostasis. Circulating total and ionized magnesium (estimated by ultrafilterable values) concentrations were determined in blood samples collected from animals after the randomized administration of placebo or 0.3, 3.0, or 30 mg/kg of endotoxin. A baseline blood sample was collected and then a second blood sample was obtained at 5, 15, 30, 60, 120, or 180 mins after endotoxin or placebo administration. In experiment 2, animals were randomized to receive magnesium-sufficient diets or magnesium-deficient diets for 6 wks. After 6 wks, the effects of the randomized administration of 3.0 mg/kg endotoxin or placebo were evaluated on mortality and analyte values (pH and blood gases, sodium, potassium, chloride, glucose, ionized calcium, hematocrit, total and ultrafilterable magnesium concentrations) in the three study groups (magnesium-sufficient, 3-wk magnesium-deficient, or 6-wk magnesium-deficient). In experiment 3, magnesium-deficient animals were randomized to receive 50 mmol/kg magnesium chloride or placebo, before or after the administration of 3.0 mg/kg of endotoxin. Baseline and 24-hr analyte determinations were performed and outcome was analyzed. MEASUREMENTS AND MAIN RESULTS: Experiment 1: Significant increases (p < .05) in circulating total magnesium concentrations were found in animals that received 30 mg/kg of endotoxin, at 120 mins (0.79 +/- 0.10 vs. 0.60 +/- 0.05 mmol/L), and 180 mins (0.74 +/- 0.04 vs. 0.56 +/- 0.04 mmol/L) compared with baseline values. Similarly, significant increases (p < .05) in ionized magnesium concentrations were observed 120 and 180 mins after 3.0 and 30 mg/kg of endotoxin compared with baseline values. Experiment 2: Magnesium deficiency was strongly (p < .02) associated with increased mortality from endotoxin challenge. Endotoxin administration (3.0 mg/kg) was lethal in 10 (43%) of 23 magnesium-sufficient animals, 15 (65%) of 23 3-wk magnesium-deficient animals, and 20 (83%) of 24 6-wk magnesium-deficient animals. Experiment 3: In magnesium-deficient animals, rats treated with magnesium replacement therapy had significantly increased survival from endotoxin administration (15 [52%] of 29 vs. five [17%] of 29, p < .01) compared with placebo-treated animals. CONCLUSIONS: a) Endotoxin challenge causes significant increases in circulating total and ionized magnesium concentrations. b) Progressive magnesium deficiency is strongly associated with increased lethality, and magnesium replacement therapy provides significant protection from endotoxin challenge. c) These experimental results support the concept that cellular injury is probably associated with increases in circulating magnesium concentrations. Furthermore, these experimental findings suggest that magnesium deficiency predisposes to worse outcome from endotoxin challenge, and that replacement therapy in the setting of magnesium deficiency may be warranted, especially in critically ill subjects.

The use and clinical importance of a substrate-specific electrode for rapid determination of blood lactate concentrations.

OBJECTIVE: To determine the validity and clinical importance of a newly developed amperometric, enzymatic, substrate-specific electrode for the rapid measurement of circulating lactate concentrations. DESIGN: A prospective multiexperiment study. SETTING: The critical care medicine research laboratory, intensive care unit (ICU), emergency department (ED), and general wards of a university-affiliated hospital. PATIENTS: A total of 1218 patients and control subjects were studied on one or more occasions. INTERVENTIONS: Blood lactate concentrations, descriptive data, physiological parameters, and outcome results were determined in various patient populations. MAIN OUTCOME MEASURES AND RESULTS: Experiment 1: Lactate determinations performed with the new substrate-specific electrode were compared with two laboratory reference methods. Blood samples from 80 ICU patients and 165 ED patients formed the basis of this first experiment. There was excellent agreement between the test instrument and the two reference methods as reflected by bias (with reference method 1, 0.19 mmol/L; reference method 2, 0.09 mmol/L), precision (with reference method 1, +/- 0.47 mmol/L; reference method 2, +/- 0.34 mmol/L), and correlation data (with reference method 1, r = .92; reference method 2, r = .98). Experiment 2: The new test microchemistry instrument was used to analyze blood samples from 927 patients. The mean (SE) blood lactate concentrations in the various patient populations were 1.26 (0.04) mmol/L for control subjects (n = 85), 1.52 (0.03) mmol/L for general ward patients (n = 489; P < .001 vs normal subjects), 2.34 (0.15) mmol/L for ICU patients (n = 180; P < .001 vs normal subjects and general ward patients), and 2.44 (0.15) mmol/L for ED patients (n = 173; P < .001 vs normal subjects and general ward patients). None of the normal subjects and only one (0.2%) of 489 nonhypotensive general ward patients had a blood lactate value greater than 4 mmol/L. Circulating lactate concentrations greater than 4 mmol/L were 98.2% specific in predicting the need for hospital admission in patients presenting to the ED. Furthermore, lactate concentrations greater than 4 mmol/L were 96% specific in predicting mortality in hospitalized nonhypotensive patients. Experiment 3: Blood samples from 46 hypotensive ICU and ED patients and from 353 nonhypotensive ICU and ED patients (the latter samples were derived from experiment 2) were analyzed. A statistically significant difference was noted between the mean (SE) lactate concentration in hypotensive patients in the ICU and ED (4.75 [0.75] mmol/L) when compared with nonhypotensive ICU and ED patients (2.28 [0.10] mmol/L; P < .001). Furthermore, blood lactate values greater than 4 mmol/L were 87.5% specific in predicting mortality in hypotensive patients. CONCLUSIONS: Lactate determinations performed using the new test instrument are precise and accurate. Blood lactate concentrations greater than 4 mmol/L are unusual in normal and noncritically ill hospitalized patients and warrant concern. In hospitalized (non-ICU) nonhypotensive subjects, as well as in critically ill patients, a blood lactate concentration greater than 4 mmol/L may portend a poor prognosis.

Ultrafilterable hypomagnesemia in neonates admitted to the neonatal intensive care unit.

OBJECTIVE: To evaluate the frequency and clinical correlates of ultrafilterable hypomagnesemia in neonates admitted to the neonatal intensive care unit (ICU). DESIGN: Prospective, observational study. SETTING: Massachusetts General Hospital and Mount Auburn Hospital. PATIENTS: A total of 117 patients (84 neonatal ICU patients and 33 normal newborns) studied over a 2-yr period of time. MEASUREMENTS: Blood samples were collected during the first 48 hrs after admission. The concentrations of magnesium (total and ultrafilterable), ionized calcium, parathyroid hormone, electrolytes, glucose and arterial blood gases were determined. RESULTS: Ultrafilterable circulating magnesium concentrations were determined in 74 of 84 neonatal ICU patients. On admission to the neonatal ICU, 23 (31.1%) of 74 neonates had ultrafilterable hypomagnesemia; two (2.7%) of 74 patients had ultrafilterable hypermagnesemia. Neonatal ICU patients had significantly lower (p < .001) ultrafilterable magnesium concentrations compared with normal neonates. Hypomagnesemic ICU patients required mechanical ventilatory support more frequently than did normomagnesemic ICU neonates (p < .05). Ionized hypocalcemia was a common finding in our patients (34 [42%] of 81). However, ultrafilterable hypomagnesemia was not statistically associated with ionized hypocalcemia (p > .05). Despite the below normal serum concentrations of ultrafilterable magnesium observed in our study, there was no impairment in parathyroid hormone secretion. CONCLUSIONS: Ultrafilterable hypomagnesemia is a common finding in neonates admitted to the ICU. Ultrafilterable hypomagnesemia is associated with the need for mechanical ventilation. To our knowledge, this is the first report of ultrafilterable magnesium concentrations in normal and sick neonates.

Perioperative glucocorticoid coverage. A reassessment 42 years after emergence of a problem.

OBJECTIVE: The authors review the historical basis for the provision of perioperative glucocorticoid coverage, and detail the evolution in the understanding of the role of the hypothalamic-pituitary-adrenal cortical (HPA) axis in response to physical stressors. New recommendations are proposed for glucocorticoid-dependent patients who require anesthesia and surgery. SUMMARY BACKGROUND DATA: In 1952, a patient developed surgery-associated adrenal insufficiency as a result of preoperative withdrawal from glucocorticoid therapy. That case report, and one other in the ensuing 12 months, prompted the publication of recommendations for perioperative glucocorticoid coverage, which became the standard of care. The understanding of the role of the HPA axis in the stress response has been subsequently refined; however, recommendations for perioperative glucocorticoid coverage have not been altered in parallel. METHODS: Studies were identified beginning with the first reports of the physiologic actions of the adrenal glands (1855) and the description and clinical use of cortisone (1930-1993). Studies were selected for review if they were related to or evaluated the provision of stress-related glucocorticoid administration. All clinical studies were evaluated to determine the basis for the provision of perioperative glucocorticoid coverage and the validity of the data used to justify these conclusions. CONCLUSIONS: Clinical and experimental evidence support the concept that the current amount of perioperative glucocorticoid coverage is excessive and has been based on anecdotal information. New recommendations are proposed which suggest that the amount and duration of glucocorticoid coverage should be determined by: a) the preoperative dose of glucocorticoid taken by the patient, b) the preoperative duration of glucocorticoid administration, and c) the nature and anticipated duration of surgery.