Abstract
Glucocorticoid preparations, adreno-cortical steroids, with strong anti-inflammatory and immunosuppressive effects, are widely used for treating various diseases. The number of patients exposed to steroid therapy prior to surgery is increasing. When these patients present for surgery, the anesthesiologist must decide whether to administer perioperative steroid supplementation. Stress-dose glucocorticoid administration is required during the perioperative period because of the possibility of failure of cortisol secretion to cope with the increased cortisol requirement due to surgical stress, adrenal insufficiency, hemodynamic instability, and the possibility of adrenal crisis. Therefore, glucocorticoids should be supplemented at the same level as that of normal physiological response to surgical stress by evaluating the invasiveness of surgery and inhibition of the hypothalamus-pituitary-adrenal axis. Various textbooks and research articles recommend the stress-dose of glucocorticoids during perioperative periods. It has been commonly suggested that glucocorticoids should be administered in an amount equivalent to about 100 mg of cortisol for major surgery because it induces approximately 5 times the normal secretion. However, more studies, with appropriate power, regarding the administration of stress-dose glucocorticoids are still required, and evaluation of patients with possible adrenal insufficiency and appropriate glucocorticoid administration based on surgical stress will help improve the prognosis.
Synthetic glucocorticoids were first introduced in 1949 after the development of a purified preparation, known as cortisone, and became a revolutionary treatment for patients with primary adrenal failure and other acute-chronic inflammatory and autoimmune diseases. In anesthesiology, it is widely used to treat reactive airway diseases, acute nerve injury, nausea or vomiting, inflammatory diseases, and excessive immunosuppression during organ transplantation or cardiopulmonary bypass [1]. Shortly after the development of synthetic cortisone, there were two case reports of perioperative secondary adrenal crisis. The two young patients on chronic cortisone therapy stopped steroids before the surgery; they suddenly died after the surgery, and the result of the autopsy showed bilateral adrenal atrophy [2,3]. Since then, it has become common practice to perioperatively administer glucocorticoids at a supra-physiological dose, the so-called stress-dose, to patients on steroid therapy for long duration and in suspected adrenal failure cases.
The number of patients exposed to steroid therapy prior to surgery is increasing as corticosteroids are widely used for systemic administration and as inhalation and topical drugs [4]. Accordingly, clinical trials and retrospective analyses have been conducted regarding stress-dose glucocorticoids administration in the perioperative period for patients on steroid therapy [5,6]. However, many clinical trials had a low level of evidence, including unclear criteria for adrenal failure with a limited number of patients, resulting in various proposed recommendations for the administration of glucocorticoids in the perioperative periods [7]. Therefore, this article reviews the physiology of adreno-cortical hormones and indications and applications of stress-dose glucocorticoids in the perioperative periods based on recently published recommendations [7,8].
Adrenocorticosteroids are steroid derivatives produced in the adrenal cortex and include three endogenous hormones: glucocorticoid, mineralocorticoid, and androgen. All of them are synthesized when cholesterol is converted to pregnenolone by the cytochrome P450 enzyme [1]. Of these, glucocorticoids are secreted from the zona fasciculata of the adrenal cortex and the most important glucocorticoid is cortisol. Cortisol is an essential hormone for maintaining life. It mediates carbohydrate and protein metabolism, fatty acid transfer, electrolyte and fluid balance, and anti-inflammatory reactions. Cortisol enables the synthesis and release of catecholamines and contributes to normal vascular permeability, vascular tone, and myocardial contraction by regulating β-receptor synthesis and regulation [1].
The secretion of adrenal cortical hormones is regulated by the hypothalamic-pituitary-adrenal (HPA) axis. The corticotropin-releasing hormone (CRH) secreted from the hypothalamus stimulates the secretion of adrenocorticotropic hormone (ACTH) in the anterior pituitary gland, and ACTH stimulates the adrenal gland. This positive feedback for cortisol secretion and negative feedback for inhibiting the secretion of CRH and ACTH due to increased cortisol concentration regulates the secretion of cortisol [1].
The secretion of cortisol changes depending on the pulsatile secretion of CRH and ACTH according to the circadian rhythm. Serum cortisol concentration reaches the highest concentration of about 15 μg/dl around 6–9 am, then drops to the lowest concentration of below 2 μg/dl around 11 pm to 1 am. The median value of the 24-h period is approximately 5.2 μg/dl [9]. In normal adults, the adrenal glands produce approximately 5 to 10 mg/m2/day (body surface area per day) of cortisol, which is equivalent to 5 to 7 mg of oral prednisone or 20 to 30 mg of hydrocortisone [10,11]. In plasma, approximately 90% of circulating cortisol binds to corticosteroid-binding globulin (CBG), an α2-globulin binding protein synthesized in the liver [12]. The remaining 5–10% binds to albumin or circulates freely and exerts an effect on target cells. When plasma cortisol concentration exceeds 20–30 μg/dl, CBG is saturated, and the concentration of free cortisol increases rapidly [12].
Sudden physiological and mental stress such as trauma, burns, major surgery, hypoglycemia, high fever, low blood pressure, severe exercise, and cold exposure activates the HPA axis and increases blood ACTH and cortisol levels. In a normal response to stress, the blood cortisol concentration increases to 18–20 μg/dl and adrenal cortisol secretion increases up to 30–45 μg/dl during moderately stressful situations and about 260 μg/dl in a highly stressful life-threatening situation. Increased cortisol levels normalize within approximately 24 to 48 h after the stress is resolved [11].
Adrenal insufficiency (AI) is the inability of the adrenal glands to produce adequate amounts of corticosteroids in response to various pathophysiologic states; this condition can be classified into primary, secondary, and tertiary AI depending on the cause [11]. Primary AI is an abnormality in the adrenal gland itself and is caused by the destruction of the adrenal cortex due to autoimmune diseases, viral and tuberculosis infection, hemorrhage, metastatic cancer, and sepsis. Secondary AI is rare but is caused by impaired production of ACTH or CRH due to damage or dysfunction caused by diseases of the pituitary gland or hypothalamus. Tertiary AI is the most common form, widely included in secondary AI, and is typically caused by inhibition of the hypothalamus or pituitary due to iatrogenic corticosteroid therapy; the degree of adrenal dysfunction is variable and sometimes reversible. In these patients, mineralocorticoid secretion is not affected and only cortisol production is reversibly inhibited [13]. Tertiary AI rarely occurs when oral prednisone dosage is less than 5 mg or when steroid is taken for a short period of less than 2 weeks, regardless of the dosage. However, AI has been reported to occur in more than 60% of patients taking high-dose oral prednisone (> 40 mg) even after only about 6 days [11,14].
Patients with long-term steroid administration or severe illness have a reduced cortisol response to stress, which causes risk of an acute adrenal crisis. Symptoms of acute adrenal crisis in awake patients are presented in Table 1 [15]. In patients under anesthesia, hypotension, which does not respond to fluid administration, has been considered the most important sign of perioperative adrenal crisis [7]. Symptoms and signs that occur earlier than hypotension include non-specific changes in consciousness and cognitive decline and persistent fever [8]. Laboratory examinations may show hypoglycemia, hyponatremia, and hyperkalemia. Since most of these symptoms are non-specific, it is necessary to exclude causes other than AI. However, since adrenal crisis is a life-threatening condition, it should be immediately recognized and corrected by the administration of stress-doses of steroids, fluids, and vasopressors [8].
Surgery causes a stress response with a wide range of endocrine, immune, and cardiovascular effects. During major surgery, proinflammatory cytokines, CRH, ACTH, and cortisol levels increase proportionally, resulting in an increase in cortisol secretion up to approximately 5–10 times the normal secretion, that is, 75–150 mg/day [16,17]. After surgery, the diurnal secretion of cortisol malfunctions temporarily, and the serum concentration of cortisol rises due to surgical stress [11].
In a recent meta-analysis, the change in serum cortisol concentration before and after surgery in patients without steroid therapy was analyzed in 71 studies since the 1990s [18]. In this study, the invasiveness of surgery was divided into three stages from grade 1 to 3 according to the modified Johns Hopkins surgical criteria [19]. Minor to moderately invasive procedures with less bleeding (potential blood loss < 500 ml) were included in grade 1; for example, breast biopsy, removal of minor skin or subcutaneous lesions, myringotomy tubes, hysteroscopy, cystoscopy, vasectomy, circumcision, fiberoptic bronchoscopy, diagnostic laparoscopy, dilatation, and curettage. Moderately to significantly invasive procedures (potential blood loss 500–1,500 ml) were included in grade 2; for example, thyroidectomy, hysterectomy, myomectomy, cystectomy, cholecystectomy, laminectomy, hip/knee replacement, nephrectomy, and major laparoscopic procedures. Highly invasive procedures (potential blood loss > 1,500 ml) were included in Grade 3, for example, major reconstruction of the gastrointestinal tract, major genitourinary surgery, cardiothoracic procedures, and intracranial procedures. In this review, it was found that the grade of surgery significantly affected cortisol secretion [18]. Patients undergoing grade 1 surgery did not show an intraoperative cortisol peak, and postsurgical cortisol concentrations were similar to those at baseline. Nevertheless, when compared to published data on healthy, unstressed adults, the mean cortisol output over the first 24 h after grade I surgical procedure was approximately doubled. Patients undergoing grade 2 and 3 surgery had 3.5–4 times higher cortisol output than that of healthy, unstressed individuals within the first 24-h postoperative period. Moreover, in both grade 2 and 3 surgeries, mean cortisol values remained elevated in comparison with the baseline measurements up to postoperative day 7.
Due to ethical issues, only a few studies have investigated the change in cortisol concentration and the incidence of AI after discontinuation of steroids in patients taking steroids. In 1973, Kehlet and Binder [16] investigated the occurrence of acute AI after steroid discontinuation in 73 patients undergoing major surgery, including splenectomy and colon resection. Patients took 5–80 mg of prednisone for various periods in this study. As a result, about 10% of patients developed perioperative hypotension, but only 3 patients showed low blood cortisol levels, and most of them were treated by fluid administration. They also measured cortisol concentration in patients undergoing major abdominal surgery and minor procedures such as hand surgery or uterine curettage, and estimated cortisol secretion due to surgical stress was found to be 75–150 mg/day and 50 mg/day for major and minor surgeries, respectively. The results of this study formed the rationale for subsequent recommendations of perioperative glucocorticoid supplementation [7,20].
De Lange and Kars [5] and Khazen and El-Hussuna [6] investigated the incidence of AI following administration of stress-doses or conventional maintenance doses of glucocorticoids based on prospective and retrospective studies. The randomized controlled trials included in their meta-analysis mostly targeted minor to moderate surgery with a limited number of patients, and both meta-analyses concluded that the incidence of perioperative AI was very low [5,6]. These studies reported that patients taking less than 5–10 mg/day of prednisone did not have adverse side effect of AI, even if only the daily dose was maintained during relatively less invasive surgery [21–23].
Despite the low incidence of surgery-induced AI, several major pathophysiologic mechanisms support the necessity of glucocorticoid administration in the perioperative period.
Glucocorticoids have a permissive effect on vascular tone and maintenance of blood pressure [24]. Glucocorticoids alone do not increase blood pressure, but when administered with a vasopressor, glucocorticoids enhance vascular reactivity to vasopressors. The effect of glucocorticoid on vascular tone is exerted by inhibition of the synthesis of prostacyclin I2 (PGI2), a potent vasodilator, in the vascular endothelium [25]. If the inhibitory effect on vascular tone disappears due to a decrease in cortisol response, it may lead to increased production of PGI2, vasodilation, and hypotension.
Cortisol is involved in catecholamine synthesis and mediates the release of catecholamine from sympathetic nerve cells by directly regulating the activity of phenylethanolamine N-methyltransferase, an enzyme that catalyzes the conversion of norepinephrine to epinephrine in the adrenal medulla [26]. Cortisol also mediates catecholamine release from sympathetic cells [27].
Cortisol helps the myocardium adapt to perioperative stress [28]. In animal studies, acute adrenal failure caused reduced myocardial contractility due to a decrease in the activity of myofibrillar adenosine triphosphatase, which is directly dependent on glucocorticoids [29]. In patients with hemodynamically unstable secondary AI, bolus intravenous hydrocortisone increases the stroke work index of the left ventricle [30].
All synthetic glucocorticoids are derivatives of cortisol, an endogenous glucocorticoid. Drugs used as therapeutic glucocorticoids include hydrocortisone, prednisolone, and dexamethasone (Table 2) [1]. Among these drugs, hydrocortisone, which has the same structure as cortisol, is the most commonly used synthetic glucocorticoid. Prednisone is an inactive prodrug that is activated to prednisolone by 11β-hydroxysteroid dehydrogenase after administration [31]. Synthetic corticosteroids have different glucocorticoid and mineralocorticoid activities. Table 2 shows the relative efficacy of commonly used corticosteroids compared to that of hydrocortisone [1]. When adrenal gland function is reduced, corticosteroids are used to replace both glucocorticoids and mineralocorticoids. Therefore, in patients with primary AI in which mineralocorticoids are not secreted, dexamethasone is not appropriate and synthetic mineralocorticoids, fludrocortisone, and hydrocortisone should be administered [7]. Secondary and tertiary AI are caused by a lack of glucocorticoids, so the administration of drugs with mineralocorticoid activity may cause side effects such as dose-dependent edema, fluid retention, and hypokalemia [7]. Therefore, when a high dose of hydrocortisone of 100 mg or more is required in patients with secondary and tertiary AI, switching to a drug with a higher glucocorticoid activity ratio than that of mineralocorticoid such as methylprednisolone should be considered [24].
Continuous administration of high doses of glucocorticoids after surgery can cause unwanted side effects [31]. Glucocorticoids promote gluconeogenesis in the liver and proteolysis and adipolysis in muscles, resulting in hyperglycemia. In addition, continuous glucocorticoid administration results in sodium retention, subsequent plasma volume increase, and intensifies vasopressor response to angiotensin II and catecholamines, leading to hypertension [32]. Glucocorticoids inhibit cytokine signaling and the synthesis of matrix metalloproteinases and collagen, which play an important role in wound healing [33]. In addition, it can cause gastrointestinal bleeding and various psychiatric symptoms [7]. However, most side effects occur in proportion to the duration of glucocorticoid administration, therefore, the incidence of side effects after short-term treatment is low even with high doses.
Glucocorticoids should be administered during the perioperative period because cortisol secretion in response to surgical stress may fail, resulting in AI, hemodynamic instability, and adrenal crisis. Therefore, the dose of glucocorticoid should be administered at the same level as that of normal physiological response to the surgical stress after evaluating the invasiveness of surgery and inhibition of the HPA axis [24]. If there is no suppression of the HPA axis or the requirement due to surgical stress does not exceed the maintenance dose of glucocorticoids already being taken, a perioperative stress-dose of glucocorticoid is not required unless the patient shows signs of AI [7]. However, when glucocorticoid requirement increases rapidly due to surgical stress, and the inhibition of the HPA axis is clinically important, the administration of stress doses should be considered [7,8].
Steroid dose and duration affect HPA axis suppression. Regardless of duration, the risk of HPA axis suppression is low if the prednisone dose taken in the morning does not exceed 5 mg/day (≈ methylprednisolone 4 mg/day, dexamethasone 0.5 mg/day, hydrocortisone 20 mg/day) or 10 mg of prednisone every other day. In addition, if any dose of glucocorticoid is administered for less than three weeks, the HPA axis is less likely to be suppressed. These patients do not require additional administration of glucocorticoids or tests to assess the HPA axis [7].
Patients on daily dose of prednisone exceeding 20 mg for a period of more than three weeks and patients with symptoms of Cushing syndrome who are taking glucocorticoids are at high risk of HPA axis suppression [7]. These patients should be administered perioperative supplemental glucocorticoids according to the invasiveness of surgery [7].
Besides these patients, patients taking prednisone at 5–20 mg/day or equivalent doses over a period of three or more weeks may experience various ranges of HPA axis suppression depending on their age, and dosage and duration of administration [34]. Even in cases with discontinued exposure of steroids, patients who inhaled high-dose steroids or high-potency topical steroids should be tested for adrenal function preoperatively and supplemental glucocorticoids should be administered based on the results of the test. There is a risk of HPA axis inhibition when inhaled glucocorticoid fluticasone ≥ 750 μg/day (or beclomethasone ≥ 1,500 μg/day ≈ prednisolone ≥ 10 mg/day) is administered for more than 3 weeks before surgery [35,36]. The absorption rate of topical steroids varies depending on the period of use, strength, and application site, but when topical steroids with high potency are used for > 2 g/day for more than 2 weeks, suppression of the HPA axis may occur [37]. In addition, patients who have received three or more intra-articular or spinal glucocorticoid injections within three months prior to surgery, have symptoms of AI, or Cushing's syndrome, the HPA axis needs to be evaluated [38].
Measurement of morning serum cortisol concentrations before 8 am after stopping glucocorticoids for 24 h is a good screening test for assessing secondary and tertiary AI symptoms [39]. If the morning serum cortisol concentration is lower than 5 μg/dl, suppression of the HPA axis may be suspected and the administration of additional glucocorticoids is required [7]. If the morning cortisol concentration is greater than 10 μg/dl, it can be considered that there is no inhibition of the HPA axis, and the usual dose of glucocorticoid is taken until the day of surgery and no additional administration is required [7]. If the morning cortisol concentration is 5 to 10 μg/dl, ACTH stimulation tests are conducted, or glucocorticoids are administered based on experience.
The ACTH stimulation test determines whether adrenal function is inhibited by administering synthetic ACTH (cosyntropin 250 μg); the concentration of serum cortisol are measured 30 min after the administration of ACTH [24]. If cortisol concentration is higher than 18 μg/dl, it can be determined that proper adrenal function is maintained and additional administration of glucocorticoid is not required [7].
Based on recent studies, recommendations were published in Anesthesiology in 2017 and Anaesthesia in 2020 [7,8]. As presented in Table 3, Liu et al. proposed recommendations based on estimated daily cortisol secretions according to the invasiveness of surgery [7,16,17].
Recently, the Royal College of Anaesthetists and the Endocrinology Society of the United Kingdom also published guidelines in Anaesthesia [8], but they are different from those of Liu et al. [7]. They have similarity in that they recommend administering stress-dose steroids to patients with primary and secondary AI and HPA axis suppression. However, they recommended 100 mg of hydrocortisone for all patients undergoing minor procedures as well as major surgeries [8]. After the publication of this recommendation, when questions arose about administering the same dose for a relatively simple operation [40], the authors responded that this dose may not be appropriate for simple procedures [41]. Therefore, we can only refer to their recommendations for major surgery. According to this guideline, for patients undergoing major surgery, hydrocortisone 100 mg or dexamethasone 6–8 mg should be administered at time of induction of anesthesia, followed by immediate initiation of a continuous infusion of hydrocortisone 200 mg/day until the patients can be administered double the pre-surgical oral dose [8].
Cortisol has a variety of critical physiological actions, and an increase in concentration due to surgical stress is important for maintaining hemodynamic stability during surgery. Although studies with more appropriate evidence are still required, evaluation of patients with possible AI and glucocorticoid administration according to surgical stress is crucial and can improve prognosis.
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