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Monday, May 27, 2019

Glucocorticoid

From Wikipedia, the free encyclopedia

Glucocorticoid
Drug class
Cortisol2.svg
Chemical structure of cortisol (hydrocortisone), an endogenous glucocorticoid as well as medication.
Class identifiers
SynonymsCorticosteroid; Glucocorticosteroid
UseAdrenal insufficiency; allergic, inflammatory, and autoimmune disorders; asthma; organ transplant
ATC codeH02AB
Biological targetGlucocorticoid receptor
Chemical classSteroids

Glucocorticoids are a class of corticosteroids, which are a class of steroid hormones. Glucocorticoids are corticosteroids that bind to the glucocorticoid receptor that is present in almost every vertebrate animal cell. The name "glucocorticoid" is a portmanteau (glucose + cortex + steroid) and is composed from its role in regulation of glucose metabolism, synthesis in the adrenal cortex, and its steroidal structure (see structure to the right). A less common synonym is glucocorticosteroid.

Glucocorticoids are part of the feedback mechanism in the immune system which reduces certain aspects of immune function, such as inflammation. They are therefore used in medicine to treat diseases caused by an overactive immune system, such as allergies, asthma, autoimmune diseases, and sepsis. Glucocorticoids have many diverse (pleiotropic) effects, including potentially harmful side effects, and as a result are rarely sold over the counter. They also interfere with some of the abnormal mechanisms in cancer cells, so they are used in high doses to treat cancer. This includes inhibitory effects on lymphocyte proliferation, as in the treatment of lymphomas and leukemias, and the mitigation of side effects of anticancer drugs.

Glucocorticoids affect cells by binding to the glucocorticoid receptor. The activated glucocorticoid receptor-glucocorticoid complex up-regulates the expression of anti-inflammatory proteins in the nucleus (a process known as transactivation) and represses the expression of proinflammatory proteins in the cytosol by preventing the translocation of other transcription factors from the cytosol into the nucleus (transrepression).

Glucocorticoids are distinguished from mineralocorticoids and sex steroids by their specific receptors, target cells, and effects. In technical terms, "corticosteroid" refers to both glucocorticoids and mineralocorticoids (as both are mimics of hormones produced by the adrenal cortex), but is often used as a synonym for "glucocorticoid." Glucocorticoids are chiefly produced in the zona fasciculata of the adrenal cortex, whereas mineralocorticoids are synthesized in the zona glomerulosa.

Cortisol (or hydrocortisone) is the most important human glucocorticoid. It is essential for life, and it regulates or supports a variety of important cardiovascular, metabolic, immunologic, and homeostatic functions. Various synthetic glucocorticoids are available; these are widely utilized in general medical practice and numerous specialties either as replacement therapy in glucocorticoid deficiency or to suppress the immune system.

Effects

Steroidogenesis showing glucocorticoids in green ellipse at right with the primary example being cortisol. It is not a strictly bounded group, but a continuum of structures with increasing glucocorticoid effect.
 
Glucocorticoid effects may be broadly classified into two major categories: immunological and metabolic. In addition, glucocorticoids play important roles in fetal development and body fluid homeostasis.

Immune

As discussed in more detail below, glucocorticoids function through interaction with the glucocorticoid receptor:
  • up-regulate the expression of anti-inflammatory proteins.
  • down-regulate the expression of proinflammatory proteins.
Glucocorticoids are also shown to play a role in the development and homeostasis of T lymphocytes. This has been shown in transgenic mice with either increased or decreased sensitivity of T cell lineage to glucocorticoids.

Metabolic

The name "glucocorticoid" derives from early observations that these hormones were involved in glucose metabolism. In the fasted state, cortisol stimulates several processes that collectively serve to increase and maintain normal concentrations of glucose in blood. 

Metabolic effects:
  • Stimulation of gluconeogenesis, in particular, in the liver: This pathway results in the synthesis of glucose from non-hexose substrates, such as amino acids and glycerol from triglyceride breakdown, and is particularly important in carnivores and certain herbivores. Enhancing the expression of enzymes involved in gluconeogenesis is probably the best-known metabolic function of glucocorticoids.
  • Mobilization of amino acids from extrahepatic tissues: These serve as substrates for gluconeogenesis.
  • Inhibition of glucose uptake in muscle and adipose tissue: A mechanism to conserve glucose
  • Stimulation of fat breakdown in adipose tissue: The fatty acids released by lipolysis are used for production of energy in tissues like muscle, and the released glycerol provide another substrate for gluconeogenesis.
  • Increase in sodium retention and potassium excretion leads to hypernatremia and hypokalemia
  • Increase in hemoglobin concentration, likely due to hindrance of the ingestion of red blood cell by macrophage or other phagocyte.
  • Increased urinary uric acid 
  • Increased urinary calcium and hypocalcemia
  • Alkalosis
  • Leukocytosis
Excessive glucocorticoid levels resulting from administration as a drug or hyperadrenocorticism have effects on many systems. Some examples include inhibition of bone formation, suppression of calcium absorption (both of which can lead to osteoporosis), delayed wound healing, muscle weakness, and increased risk of infection. These observations suggest a multitude of less-dramatic physiologic roles for glucocorticoids.

Developmental

Glucocorticoids have multiple effects on fetal development. An important example is their role in promoting maturation of the lung and production of the surfactant necessary for extrauterine lung function. Mice with homozygous disruptions in the corticotropin-releasing hormone gene (see below) die at birth due to pulmonary immaturity. In addition, glucocorticoids are necessary for normal brain development, by initiating terminal maturation, remodeling axons and dendrites, and affecting cell survival and may also play a role in hippocampal development. Glucocorticoids stimulate the maturation of the Na+/K+/ATPase, nutrient transporters, and digestion enzymes, promoting the development of a functioning gastro-intestinal system. Glucocorticoids also support the development of the neonate's renal system by increasing glomerular filtration.

Arousal and cognition

A graphical representation of the Yerkes-Dodson curve
A graphical representation of the Yerkes-Dodson curve
 
Glucocorticoids act on the hippocampus, amygdala, and frontal lobes. Along with adrenaline, these enhance the formation of flashbulb memories of events associated with strong emotions, both positive and negative. This has been confirmed in studies, whereby blockade of either glucocorticoids or noradrenaline activity impaired the recall of emotionally relevant information. Additional sources have shown subjects whose fear learning was accompanied by high cortisol levels had better consolidation of this memory (this effect was more important in men). The effect that glucocorticoids have on memory may be due to damage specifically to the CA1 area of the hippocampal formation. In multiple animal studies, prolonged stress (causing prolonged increases in glucocorticoid levels) have shown destruction of the neurons in this area of the brain, which has been connected to lower memory performance.

Glucocorticoids have also been shown to have a significant impact on vigilance (attention deficit disorder) and cognition (memory). This appears to follow the Yerkes-Dodson curve, as studies have shown circulating levels of glucocorticoids vs. memory performance follow an upside-down U pattern, much like the Yerkes-Dodson curve. For example, long-term potentiation (LTP; the process of forming long-term memories) is optimal when glucocorticoid levels are mildly elevated, whereas significant decreases of LTP are observed after adrenalectomy (low-glucocorticoid state) or after exogenous glucocorticoid administration (high-glucocorticoid state). Elevated levels of glucocorticoids enhance memory for emotionally arousing events, but lead more often than not to poor memory for material unrelated to the source of stress/emotional arousal. In contrast to the dose-dependent enhancing effects of glucocorticoids on memory consolidation, these stress hormones have been shown to inhibit the retrieval of already stored information. Long-term exposure to glucocorticoid medications, such as asthma and anti-inflammatory medication, has been shown to create deficits in memory and attention both during and, to a lesser extent, after treatment, a condition known as "steroid dementia."

Body fluid homeostasis

Glucocorticoids could act centrally, as well as peripherally, to assist in the normalization of extracellular fluid volume by regulating body's action to atrial natriuretic peptide (ANP). Centrally, glucocorticoids could inhibit dehydration induced water intake; peripherally, glucocorticoids could induce a potent diuresis.

Mechanism of action

Transactivation

Glucocorticoids bind to the cytosolic glucocorticoid receptor, a type of nuclear receptor that is activated by ligand binding. After a hormone binds to the corresponding receptor, the newly formed complex translocates itself into the cell nucleus, where it binds to glucocorticoid response elements in the promoter region of the target genes resulting in the regulation of gene expression. This process is commonly referred to as transcriptional activation, or transactivation.

The proteins encoded by these up-regulated genes have a wide range of effects, including, for example:

Transrepression

The opposite mechanism is called transcriptional repression, or transrepression. The classical understanding of this mechanism is that activated glucocorticoid receptor binds to DNA in the same site where another transcription factor would bind, which prevents the transcription of genes that are transcribed via the activity of that factor. While this does occur, the results are not consistent for all cell types and conditions; there is no generally accepted, general mechanism for transrepression.

New mechanisms are being discovered where transcription is repressed, but the activated glucocorticoid receptor is not interacting with DNA, but rather with another transcription factor directly, thus interfering with it, or with other proteins that interfere with the function of other transcription factors. This latter mechanism appears to be the most likely way that activated glucocorticoid receptor interferes with NF-κB - namely by recruiting histone deacetylase, which deacetylate the DNA in the promoter region leading to closing of the chromatin structure where NF-κB needs to bind.

Nongenomic effects

Activated glucocorticoid receptor has effects that have been experimentally shown to be independent of any effects on transcription and can only be due to direct binding of activated glucocorticoid receptor with other proteins or with mRNA.

For example, Src kinase which binds to inactive glucocorticoid receptor, is released when a glucocorticoid binds to glucocorticoid receptor, and phosphorylates a protein that in turn displaces an adaptor protein from a receptor important in inflammation, epidermal growth factor, reducing its activity, which in turn results in reduced creation of arachidonic acid - a key proinflammatory molecule. This is one mechanism by which glucocorticoids have an anti-inflammatory effect.

Pharmacology

Dexamethasone - a synthetic glucocorticoid binds more powerfully to the glucocorticoid receptor than cortisol does. Dexamethasone is based on the cortisol structure but differs at three positions (extra double bond in the A-ring between carbons 1 and 2 and addition of a 9-α-fluoro group and a 16-α-methyl substituent).
 
A variety of synthetic glucocorticoids, some far more potent than cortisol, have been created for therapeutic use. They differ in both pharmacokinetics (absorption factor, half-life, volume of distribution, clearance) and pharmacodynamics (for example the capacity of mineralocorticoid activity: retention of sodium (Na+) and water; renal physiology). Because they permeate the intestines easily, they are administered primarily per orem (by mouth), but also by other methods, such as topically on skin. More than 90% of them bind different plasma proteins, though with a different binding specificity. Endogenous glucocorticoids and some synthetic corticoids have high affinity to the protein transcortin (also called corticosteroid-binding globulin), whereas all of them bind albumin. In the liver, they quickly metabolize by conjugation with a sulfate or glucuronic acid, and are secreted in the urine

Glucocorticoid potency, duration of effect, and the overlapping mineralocorticoid potency vary. Cortisol is the standard of comparison for glucocorticoid potency. Hydrocortisone is the name used for pharmaceutical preparations of cortisol. 

The data below refer to oral administration. Oral potency may be less than parenteral potency because significant amounts (up to 50% in some cases) may not reach the circulation. Fludrocortisone acetate and deoxycorticosterone acetate are, by definition, mineralocorticoids rather than glucocorticoids, but they do have minor glucocorticoid potency and are included in this table to provide perspective on mineralocorticoid potency.

Comparative oral corticosteroid potencies
Name Glucocorticoid potency Mineralocorticoid potency Terminal half-life (hours)
Cortisol (hydrocortisone) 1 1 8
Cortisone 0.8 0.8 8
Prednisone 3.5–5 0.8 16–36
Prednisolone 4 0.8 16–36
Methylprednisolone 5–7.5 0.5 18–40
Dexamethasone 25–80 0 36–54
Betamethasone 25–30 0 36–54
Triamcinolone 5 0 12–36
Fludrocortisone acetate 15 200 24
Deoxycorticosterone acetate 0 20 -

Therapeutic use

Glucocorticoids may be used in low doses in adrenal insufficiency. In much higher doses, oral or inhaled glucocorticoids are used to suppress various allergic, inflammatory, and autoimmune disorders. Inhaled glucocorticoids are the second-line treatment for asthma. They are also administered as post-transplantory immunosuppressants to prevent the acute transplant rejection and the graft-versus-host disease. Nevertheless, they do not prevent an infection and also inhibit later reparative processes. Newly emerging evidence showed that glucocorticoids could be used in the treatment of heart failure to increase the renal responsiveness to diuretics and natriuretic peptides. Glucocorticoids are historically used for pain relief in inflammatory conditions. However, corticosteroids show limited efficacy in pain relief and potential adverse events for their use in tendinopathies.

Physiological replacement

Any glucocorticoid can be given in a dose that provides approximately the same glucocorticoid effects as normal cortisol production; this is referred to as physiologic, replacement, or maintenance dosing. This is approximately 6–12 mg/m²/day of hydrocortisone (m² refers to body surface area (BSA), and is a measure of body size; an average man's BSA is 1.9 m²).

Therapeutic immunosuppression

Glucocorticoids cause immunosuppression, and the therapeutic component of this effect is mainly the decreases in the function and numbers of lymphocytes, including both B cells and T cells

The major mechanism for this immunosuppression is through inhibition of nuclear factor kappa-light-chain-enhancer of activated B cells(NF-κB). NF-κB is a critical transcription factor involved in the synthesis of many mediators (i.e., cytokines) and proteins (i.e., adhesion proteins) that promote the immune response. Inhibition of this transcription factor, therefore, blunts the capacity of the immune system to mount a response.

Glucocorticoids suppress cell-mediated immunity by inhibiting genes that code for the cytokines IL-1, IL-2, IL-3, IL-4, IL-5, IL-6, IL-8 and IFN-γ, the most important of which is IL-2. Smaller cytokine production reduces the T cell proliferation.

Glucocorticoids, however, not only reduce T cell proliferation, but also lead to another well known effect - glucocorticoid-induced apoptosis. The effect is more prominent in immature T cells still inside in the thymus, but peripheral T cells are also affected. The exact mechanism regulating this glucocorticoid sensitivity lies in the Bcl-2 gene.

Glucocorticoids also suppress the humoral immunity, thereby causing a humoral immune deficiency. Glucocorticoids cause B cells to express smaller amounts of IL-2 and of IL-2 receptors. This diminishes both B cell clone expansion and antibody synthesis. The diminished amounts of IL-2 also cause fewer T lymphocyte cells to be activated. 

The effect of glucocorticoids on Fc receptor expression in immune cells is complicated. Dexamethasone decreases IFN-gamma simulated Fc gamma RI expression in neutrophils while conversely causing an increase in monocytes. Glucocorticoids may also decrease the expression of Fc receptors in macrophages, but the evidence supporting this regulation in earlier studies has been questioned. The effect of Fc receptor expression in macrophages is important since it is necessary for the phagocytosis of opsonised cells. This is because Fc receptors bind antibodies attached to cells targeted for destruction by macrophages.

Anti-inflammatory

Glucocorticoids are potent anti-inflammatories, regardless of the inflammation's cause; their primary anti-inflammatory mechanism is lipocortin-1 (annexin-1) synthesis. Lipocortin-1 both suppresses phospholipase A2, thereby blocking eicosanoid production, and inhibits various leukocyte inflammatory events (epithelial adhesion, emigration, chemotaxis, phagocytosis, respiratory burst, etc.). In other words, glucocorticoids not only suppress immune response, but also inhibit the two main products of inflammation, prostaglandins and leukotrienes. They inhibit prostaglandin synthesis at the level of phospholipase A2 as well as at the level of cyclooxygenase/PGE isomerase (COX-1 and COX-2), the latter effect being much like that of NSAIDs, thus potentiating the anti-inflammatory effect. 

In addition, glucocorticoids also suppress cyclooxygenase expression.

Glucocorticoids marketed as anti-inflammatories are often topical formulations, such as nasal sprays for rhinitis or inhalers for asthma. These preparations have the advantage of only affecting the targeted area, thereby reducing side effects or potential interactions. In this case, the main compounds used are beclometasone, budesonide, fluticasone, mometasone and ciclesonide. In rhinitis, sprays are used. For asthma, glucocorticoids are administered as inhalants with a metered-dose or dry powder inhaler.

Hyperaldosteronism

Glucocorticoids can be used in the management of familial hyperaldosteronism type 1. They are not effective, however, for use in the type 2 condition.

Resistance

Corticosteroid resistance mechanisms
 
Resistance to the therapeutic uses of glucocorticoids can present difficulty; for instance, 25% of cases of severe asthma may be unresponsive to steroids. This may be the result of genetic predisposition, ongoing exposure to the cause of the inflammation (such as allergens), immunological phenomena that bypass glucocorticoids, and pharmacokinetic disturbances (incomplete absorption or accelerated excretion or metabolism).

Heart failure

Glucocorticoids could be used in the treatment of decompensated heart failure to potentiate renal responsiveness to diuretics, especially in heart failure patients with refractory diuretic resistance with large doses of loop diuretics.

Side effects

Glucocorticoid drugs currently being used act nonselectively, so in the long run they may impair many healthy anabolic processes. To prevent this, much research has been focused recently on the elaboration of selectively acting glucocorticoid drugs. Side effects include:
In high doses, hydrocortisone (cortisol) and those glucocorticoids with appreciable mineralocorticoid potency can exert a mineralocorticoid effect as well, although in physiologic doses this is prevented by rapid degradation of cortisol by 11β-hydroxysteroid dehydrogenase isoenzyme 2 (11β-HSD2) in mineralocorticoid target tissues. Mineralocorticoid effects can include salt and water retention, extracellular fluid volume expansion, hypertension, potassium depletion, and metabolic alkalosis.

Immunodeficiency

Glucocorticoids cause immunosuppression, decreasing the function and/or numbers of neutrophils, lymphocytes (including both B cells and T cells), monocytes, macrophages, and the anatomical barrier function of the skin. This suppression, if large enough, can cause manifestations of immunodeficiency, including T cell deficiency, humoral immune deficiency and neutropenia

Main pathogens of concern in glucocorticoid-induced immunodeficiency:
Bacteria
Fungi
Viruses
Other

Withdrawal

In addition to the effects listed above, use of high-dose steroids for more than a week begins to produce suppression of the patient's adrenal glands because the exogenous glucocorticoids suppress hypothalamic corticotropin-releasing hormone and pituitary adrenocorticotropic hormone. With prolonged suppression, the adrenal glands atrophy (physically shrink), and can take months to recover full function after discontinuation of the exogenous glucocorticoid. 

During this recovery time, the patient is vulnerable to adrenal insufficiency during times of stress, such as illness. While suppressive dose and time for adrenal recovery vary widely, clinical guidelines have been devised to estimate potential adrenal suppression and recovery, to reduce risk to the patient. The following is one example:
  • If patients have been receiving daily high doses for five days or less, they can be abruptly stopped (or reduced to physiologic replacement if patients are adrenal-deficient). Full adrenal recovery can be assumed to occur by a week afterward.
  • If high doses were used for six to 10 days, reduce to replacement dose immediately and taper over four more days. Adrenal recovery can be assumed to occur within two to four weeks of completion of steroids.
  • If high doses were used for 11–30 days, cut immediately to twice replacement, and then by 25% every four days. Stop entirely when dose is less than half of replacement. Full adrenal recovery should occur within one to three months of completion of withdrawal.
  • If high doses were used more than 30 days, cut dose immediately to twice replacement, and reduce by 25% each week until replacement is reached. Then change to oral hydrocortisone or cortisone as a single morning dose, and gradually decrease by 2.5 mg each week. When the morning dose is less than replacement, the return of normal basal adrenal function may be documented by checking 0800 cortisol levels prior to the morning dose; stop drugs when 0800 cortisol is 10 μg/dl. Predicting the time to full adrenal recovery after prolonged suppressive exogenous steroids is difficult; some people may take nearly a year.
  • Flare-up of the underlying condition for which steroids are given may require a more gradual taper than outlined above.

Corticosteroid

From Wikipedia, the free encyclopedia

Corticosteroid
Drug class
Cortisol2.svg
Cortisol (hydrocortisone), a corticosteroid with both glucocorticoid and mineralocorticoid activity and effects.
Class identifiers
SynonymsCorticoid
UseVarious
ATC codeH02
Biological targetGlucocorticoid receptor, Mineralocorticoid receptor
Chemical classSteroids

Corticosteroids are a class of steroid hormones that are produced in the adrenal cortex of vertebrates, as well as the synthetic analogues of these hormones. Two main classes of corticosteroids, glucocorticoids and mineralocorticoids, are involved in a wide range of physiological processes, including stress response, immune response, and regulation of inflammation, carbohydrate metabolism, protein catabolism, blood electrolyte levels, and behavior.

Some common naturally occurring steroid hormones are cortisol (C
21
H
30
O
5
), corticosterone (C
21
H
30
O
4
), cortisone (C
21
H
28
O
5
) and aldosterone (C
21
H
28
O
5
). (Note that aldosterone and cortisone share the same chemical formula but the structures are different.) The main corticosteroids produced by the adrenal cortex are cortisol and aldosterone.

Classes

Medical uses

Synthetic pharmaceutical drugs with corticosteroid-like effects are used in a variety of conditions, ranging from brain tumors to skin diseases. Dexamethasone and its derivatives are almost pure glucocorticoids, while prednisone and its derivatives have some mineralocorticoid action in addition to the glucocorticoid effect. Fludrocortisone (Florinef) is a synthetic mineralocorticoid. Hydrocortisone (cortisol) is typically used for replacement therapy, e.g. for adrenal insufficiency and congenital adrenal hyperplasia

Medical conditions treated with systemic corticosteroids:
Topical formulations are also available for the skin, eyes (uveitis), lungs (asthma), nose (rhinitis), and bowels. Corticosteroids are also used supportively to prevent nausea, often in combination with 5-HT3 antagonists (e.g. ondansetron).

Typical undesired effects of glucocorticoids present quite uniformly as drug-induced Cushing's syndrome. Typical mineralocorticoid side-effects are hypertension (abnormally high blood pressure), hypokalemia (low potassium levels in the blood), hypernatremia (high sodium levels in the blood) without causing peripheral edema, metabolic alkalosis and connective tissue weakness. Wound healing or ulcer formation may be inhibited by the immunosuppressive effects. 

Clinical and experimental evidence indicates that corticosteroids can cause permanent eye damage by inducing central serous retinopathy (CSR, also known as central serous chorioretinopathy, CSC). A variety of steroid medications, from anti-allergy nasal sprays (Nasonex, Flonase) to topical skin creams, to eye drops (Tobradex), to prednisone have been implicated in the development of CSR.

Corticosteroids have been widely used in treating people with traumatic brain injury. A systematic review identified 20 randomised controlled trials and included 12,303 participants, then compared patients who received corticosteroids with patients who received no treatment. The authors recommended people with traumatic head injury should not be routinely treated with corticosteroids.

Pharmacogenetics

Asthma

Patients' response to inhaled corticosteroids has some basis in genetic variations. Two genes of interest are CHRH1 (corticotropin-releasing hormone receptor 1) and TBX21 (transcription factor T-bet). Both genes display some degree of polymorphic variation in humans, which may explain how some patients respond better to inhaled corticosteroid therapy than others. However, not all asthma patients respond to corticosteroids and large sub groups of asthma patients are corticosteroid resistant.\

Adverse effects

Lower arm of a 47-year-old female showing skin damage caused by topical corticosteroid use.
 
Use of corticosteroids has numerous side-effects, some of which may be severe:
  • Severe amebic colitis: Fulminant amebic colitis is associated with high case fatality and can occur in patients infected with the parasite Entamoeba histolytica after exposure to corticosteroid medications.
  • Neuropsychiatric: steroid psychosis, and anxiety, depression. Therapeutic doses may cause a feeling of artificial well-being ("steroid euphoria"). The neuropsychiatric effects are partly mediated by sensitization of the body to the actions of adrenaline. Therapeutically, the bulk of corticosteroid dose is given in the morning to mimic the body's diurnal rhythm; if given at night, the feeling of being energized will interfere with sleep. An extensive review is provided by Flores and Gumina.
  • Cardiovascular: Corticosteroids can cause sodium retention through a direct action on the kidney, in a manner analogous to the mineralocorticoid aldosterone. This can result in fluid retention and hypertension.
  • Metabolic: Corticosteroids cause a movement of body fat to the face and torso, resulting in "moon face", "buffalo hump", and "pot belly" or "beer belly", and cause movement of body fat away from the limbs. This has been termed corticosteroid-induced lipodystrophy. Due to the diversion of amino-acids to glucose, they are considered anti-anabolic, and long term therapy can cause muscle wasting.
  • Endocrine: By increasing the production of glucose from amino-acid breakdown and opposing the action of insulin, corticosteroids can cause hyperglycemia, insulin resistance and diabetes mellitus.
  • Skeletal: Steroid-induced osteoporosis may be a side-effect of long-term corticosteroid use. Use of inhaled corticosteroids among children with asthma may result in decreased height.
  • Gastro-intestinal: While cases of colitis have been reported, corticosteroids are often prescribed when the colitis, although due to suppression of the immune response to pathogens, should be considered only after ruling out infection or microbe/fungal overgrowth in the gastrointestinal tract. While the evidence for corticosteroids causing peptic ulceration is relatively poor except for high doses taken for over a month, the majority of doctors as of 2010 still believe this is the case, and would consider protective prophylactic measures.
  • Eyes: chronic use may predispose to cataract and retinopathy.
  • Vulnerability to infection: By suppressing immune reactions (which is one of the main reasons for their use in allergies), steroids may cause infections to flare up, notably candidiasis.
  • Pregnancy: Corticosteroids have a low but significant teratogenic effect, causing a few birth defects per 1,000 pregnant women treated. Corticosteroids are therefore contraindicated in pregnancy.
  • Habituation: Topical steroid addiction (TSA) or red burning skin has been reported in long-term users of topical steroids (users who applied topical steroids to their skin over a period of weeks, months, or years). TSA is characterised by uncontrollable, spreading dermatitis and worsening skin inflammation which requires a stronger topical steroid to get the same result as the first prescription. When topical steroid medication is lost, the skin experiences redness, burning, itching, hot skin, swelling, and/or oozing for a length of time. This is also called 'red skin syndrome' or 'topical steroid withdrawal'(TSW). After the withdrawal period is over the atopic dermatitis can cease or is less severe than it was before.
  • In children the short term use of steroids by mouth increases the risk of vomiting, behavioral changes, and sleeping problems.

Biosynthesis

Steroidogenesis, including corticosteroid biosynthesis.
 
The corticosteroids are synthesized from cholesterol within the adrenal cortex. Most steroidogenic reactions are catalysed by enzymes of the cytochrome P450 family. They are located within the mitochondria and require adrenodoxin as a cofactor (except 21-hydroxylase and 17α-hydroxylase).

Aldosterone and corticosterone share the first part of their biosynthetic pathway. The last part is mediated either by the aldosterone synthase (for aldosterone) or by the 11β-hydroxylase (for corticosterone). These enzymes are nearly identical (they share 11β-hydroxylation and 18-hydroxylation functions), but aldosterone synthase is also able to perform an 18-oxidation. Moreover, aldosterone synthase is found within the zona glomerulosa at the outer edge of the adrenal cortex; 11β-hydroxylase is found in the zona fasciculata and zona glomerulosa.

Classification

By chemical structure

In general, corticosteroids are grouped into four classes, based on chemical structure. Allergic reactions to one member of a class typically indicate an intolerance of all members of the class. This is known as the "Coopman classification".

The highlighted steroids are often used in the screening of allergies to topical steroids.

Group A – Hydrocortisone type

Group B – Acetonides (and related substances)

Group C – Betamethasone type

Group D – Esters

Group D1 – Halogenated (less labile)
Group D2 – Labile prodrug esters

By route of administration

Topical steroids

For use topically on the skin, eye, and mucous membranes

Topical corticosteroids are divided in potency classes I to IV in most countries (A to D in Japan). Seven categories are used in the United States to determine the level of potency of any given topical corticosteroid.

Inhaled steroids

For nasal mucosa, sinuses, bronchii, and lungs. This group includes:
There also exist certain combination preparations such as Advair Diskus in the United States, containing fluticasone propionate and salmeterol (a long-acting bronchodilator), and Symbicort, containing budesonide and formoterol fumarate dihydrate (another long-acting bronchodilator). They are both approved for use in children over 12 years old.

Oral forms

Such as prednisone, prednisolone, methylprednisolone, or dexamethasone.

Systemic forms

Available in injectables for intravenous and parenteral routes.

History

Introduction of early corticosteroids
Corticosteroid Introduced
Cortisone 1948
Hydrocortisone 1951
Fludrocortisone acetate 1954
Prednisolone 1955
Prednisone 1955
Methylprednisolone 1956
Triamcinolone 1956
Dexamethasone 1958
Betamethasone 1958
Triamcinolone acetonide 1958
Fluorometholone 1959

Tadeusz Reichstein, Edward Calvin Kendall. and Philip Showalter Hench were awarded the Nobel Prize for Physiology and Medicine in 1950 for their work on hormones of the adrenal cortex, which culminated in the isolation of cortisone.

Initially hailed as a miracle cure and liberally prescribed during the 1950s, steroid treatment brought about adverse events of such a magnitude that the next major category of anti-inflammatory drugs, the nonsteroidal anti-inflammatory drugs (NSAIDs), was so named in order to demarcate from the opprobrium. Corticosteroids were voted Allergen of the Year in 2005 by the American Contact Dermatitis Society.

Lewis Sarett of Merck & Co. was the first to synthesize cortisone, using a 36-step process that started with deoxycholic acid, which was extracted from ox bile. The low efficiency of converting deoxycholic acid into cortisone led to a cost of US $200 per gram. Russell Marker, at Syntex, discovered a much cheaper and more convenient starting material, diosgenin from wild Mexican yams. His conversion of diosgenin into progesterone by a four-step process now known as Marker degradation was an important step in mass production of all steroidal hormones, including cortisone and chemicals used in hormonal contraception.

In 1952, D.H. Peterson and H.C. Murray of Upjohn developed a process that used Rhizopus mold to oxidize progesterone into a compound that was readily converted to cortisone. The ability to cheaply synthesize large quantities of cortisone from the diosgenin in yams resulted in a rapid drop in price to US $6 per gram, falling to $0.46 per gram by 1980. Percy Julian's research also aided progress in the field. The exact nature of cortisone's anti-inflammatory action remained a mystery for years after, however, until the leukocyte adhesion cascade and the role of phospholipase A2 in the production of prostaglandins and leukotrienes was fully understood in the early 1980s.

Etymology

The cortico- part of the name refers to the adrenal cortex, which makes these steroid hormones. Thus a corticosteroid is a "cortex steroid".

Introduction to entropy

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