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Miscellaneous Systemic Drugs
Questions
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Q40.1 What are several important drug interactions with anticholinergic drugs discussed in this chapter? ( Pg. 446)
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Q40.2 What are several factors which increase the risk of myopathy from attenuated androgens? (Pg. 447)
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Q40.3 What are some of the properties of biotin which led to its clinical use for hair and nail disorders? (Pg. 447)
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Q40.4 What is the most common adverse effect of clofazimine? (Pg. 450x2)
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Q40.5 What is the mechanism of action for colchicine, and how does this mechanism and other drug properties make the drug well suited for neutrophilic dermatoses? (Pg. 450)
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Q40.6 What are several measures that reduce the common colchicine gastrointestinal effects? (Pg. 451)
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Q40.7 What are several of the mechanisms by which niacinamide acts as an anti-inflammatory drug? (Pg. 453)
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Q40.8 By what mechanisms are selective and nonselective COX-2 inhibitors potentially effective for chemoprevention of malignancies in high-risk populations? (Pg. 455)
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Q40.9 What are several of the most common cutaneous adverse reactions to penicillamine? (Pg. 456)
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Q40.10 What is the most important systemic adverse effect of potassium iodide? (Pg. 457x2)
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Q40.11 What are several of the most common mucocutaneous adverse effects of potassium iodide? (Pg. 457)
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Q40.12 Which cytokines of central importance to inflammation do thalidomide inhibit? (Pg. 458)
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Q40.13 Aside from teratogenicity, what is the most important adverse effect from thalidomide? (Pgs. 460, 461)
Abbreviations used in this chapter
ACTH
Adrenocorticotropic hormone
AE
Adverse effects
C1 INH
Complement 1 ( esterase ) inhibitor
cAMP PDE
Cyclic adenosine monophosphate phosphodiesterase
CBC
Complete blood count
CCLE
Chronic cutaneous lupus erythematosus
CKD
Chronic kidney disease
CNS
Central nervous system
CYP
Cytochrome P-450
ENL
Erythema nodosum leprosum
FAE
Fumaric acid esters
FDA
US Food and Drug Administration
GI
Gastrointestinal
GVHD
Graft-versus-host disease
HIV
Human immunodeficiency virus
IFN-γ
Interferon-γ
IgA
Immunoglobulin A
INR
International normalized ratio
LE
Lupus erythematosus
NSAID
Nonsteroidal anti-inflammatory drug
PARP-1
Poly (ADP-ribose) polymerase-1
PG
Pyoderma gangrenosum
PMN
Polymorphonuclear neutrophil
PSS
Progressive systemic sclerosis
PUVA
Psoralen and ultraviolet A
SCLE
Subacute cutaneous lupus erythematosus
SNAP
Sensory nerve amplitude potential
STEPS
System for Thalidomide Education and Prescribing Safety
TNF-α
Tumor necrosis factor-α
TSH
Thyroid-stimulating hormone
UVB
Ultraviolet B
Acknowledgment
The authors would like to acknowledge Drs. Keith G. LeBlanc Jr. and Alfred L. Knable Jr. for the contributions to the previous edition of this chapter.
Introduction
The drugs discussed in this chapter ( Table 40.1 ) have disparate structures and mechanisms of action and are used in relatively unique circumstances in dermatologic care, often after more familiar remedies fail. Some of these medications can be found over-the-counter at the corner grocery store. Others carry such significant risks that they are available only in strictly controlled circumstances. Some cost very little, whereas for others, cost may prove prohibitive. Although many of these drugs have limited US Food and Drug Administration (FDA) indications for dermatologic use, many of the drugs discussed in this chapter are increasingly being used as data to support their efficacy accumulate.
Table 40.1
Miscellaneous Systemic Drugs
| Generic Name | Trade Name | Generic Available | Manufacturer | Tablet/Capsule Sizes | Special Formulations | Standard Dosage Range |
|---|---|---|---|---|---|---|
| Glycopyrrolate | Robinul (Forte) | Yes | Various | 1, 2 mg | IV form available as preoperative med | 1–2 mg BID/TID |
| Oxybutynin | Ditropan and Ditropan XL | Yes | Various | 5 mg; ER 5, 10, 15 mg | Solution 5 mg/5 mL | 5 mg BID-TID (ER 5-15 mg qd) |
| Gabapentin | Neurontin, Gralise | Yes | various | 100, 300, 400 mg capsules, 600, 800 mg tablet | Solution 50 mg/mL | 300-1200 mg qd-TID |
| Pregabalin | Lyrica, Lyrica CR | Yes | Various | 25, 50, 75, 100, 150, 200, 225, 300 mg capsules | Solution 20 mg/mL | 150-300 mg/day divided bid-tid |
| Danazol | Danocrine | Yes | Sanofi Winthrop | 50, 100, 200 mg capsules | None | 200 mg BID/TID and taper |
| Biotin | Various | Yes | Various | 300-5000 μg | None | 2500 μg/day |
| Clofazimine | Lamprene | No | Novartis | 50 mg | None | 50–100 mg/day, plus monthly bolus 300 mg |
| Colchicine | Colcrys | Yes | AR Scientific | 0.5 mg; 0.6 mg tablets | None | 0.6 mg BID |
| Niacinamide | Various | Yes | Various | 50, 100, 125, 250, 500 mg tablets | None | 300–500 mg TID |
| Penicillamine | Cuprimine | Yes | Merck | 250 mg | None | 250 mg/day, slowly ↑ to 750–1500 mg/day |
| Potassium iodide | SSKI | Yes | Upshear-Smith | None | Solution: 1 g/mL | 5 drops BID/TID increasing to ≥15 drops TID |
| Thalidomide | Thalomid | No | Celgene | 50 mg | None | 50–300 mg/day |
| Vitamin E | Various | Yes | Various | 100–1000 IU | Drops 50 mg/mL | 200–1600 IU/day |
| Zinc sulfate | Various | Yes | Various | 220 mg | IV form for TPN | 1–2 mg/kg/day |
Bid, Twice per day; IV, intravenous; pre-op , preoperative; TID , 3 times per day; TPN , total parenteral nutrition.
Anticholinergic Agents—Glycopyrrolate and Oxybutynin
Systemic anticholinergic drugs for the symptomatic treatment of hyperhidrosis have been used for decades. There are multiple atropine-like agents available; however, atropine itself is seldom used because of its relatively frequent adverse ophthalmologic effects, such as blurring of vision. Glycopyrrolate and oxybutynin are the most frequently used anticholinergic agents.
Absorption after oral administration is variable. This may partly explain why clinical effects from these medications vary so much from one patient to the next. Individual sensitivity to a given drug’s anticholinergic effects is also likely to be partially responsible. It is often necessary for multiple drugs from this class to be tried before finding one that adequately controls a given patient’s symptoms at a tolerable dose. Anticholinergic agents ultimately work by blocking the effect of acetylcholine on sweat glands, thereby reducing perspiration.
Glycopyrrolate is usually prescribed in doses of 1 to 2 mg, 1 to 3 times daily. Oxybutynin has been evaluated in randomized trials and is effective at doses of 5 to 10 mg per day. These medications can be gradually titrated to higher doses if anticholinergic symptoms are tolerated. Reduction in hyperhidrosis often occurs within a matter of days; unfortunately, adverse effects (AE) are common at effective doses. Less serious symptoms include dryness of the mouth and blurred vision. More serious problems are rare, but include glaucoma, hyperthermia, and seizures. Use should be avoided in older adults because of increased risk for AE.
Q40.1 Coadministration of these drugs with several medications, such as the tricyclic antidepressants, olanzapine, and other medications with anticholinergic properties, may lead to increased anticholinergic AE. In addition, the pharmacologic effects of atenolol and digoxin may be increased by the simultaneous use of anticholinergic agents. The antipsychotic effects of the phenothiazines may be decreased. The package inserts for these two medications should be consulted before prescribing either of the drugs, for a more thorough discussion of possible drug interactions.
Although these agents are sometimes poorly tolerated, a significant number of patients’ symptoms are well controlled at low doses without appreciable AE. Given the reasonable possibility of success, a trial with anticholinergic medication is usually warranted before pursuing more invasive, expensive therapies for hyperhidrosis such as botulinum toxin injections. One invasive procedure of interest for hyperhidrosis is percutaneous transthoracic endoscopic partial sympathectomy; clinicians are encouraged to proceed with caution, concerning this relatively new and potentially risky surgical technique. This should be reserved for patients with severe hyperhidrosis not controlled by other modalities, given the risk for Horner syndrome and compensatory hyperhidrosis following the procedure. Botulinum toxin has a significant role in management of hyperhidrosis as well (see Chapter 60 ).
Attenuated Androgens—Danazol
Synthetic derivatives of testosterone, danazol and stanozolol, have impressive anabolic properties and markedly attenuated androgenic properties. Although stanozolol is no longer marketed in most countries, including the United States, danazol remains available and FDA approved for management of hereditary angioedema. Attenuated androgens have potent fibrinolytic activity and have been used to treat lipodermatosclerosis, cryofibrinogenemia, and livedoid vasculopathy.
Pharmacology
Danazol is alkylated in position 17-α, which causes a marked decrease in hepatic degradation and permits oral administration. A pyrazole ring attached to the steroid nucleus is thought to be responsible for its high anabolic/androgenic ratio.
Mechanism of Action
Attenuated androgens increase concentrations of liver-synthesized plasma glycoproteins, including several clotting factors and the inhibitor of the first component of complement. Altered synthesis of hepatic proteins involved in the fibrinolytic process results in potent fibrinolytic properties.
Clinical use
Us Food and Drug Administration-Approved Indication
Hereditary Angioedema
For prevention of attacks of hereditary angioedema, danazol therapy is initiated at a dose of 200 mg 2 or 3 times daily (see package insert). After edematous episodes are successfully prevented, the dose is slowly titrated downward to the lowest dose that will suppress life-threatening bouts of the disease. Long-term prophylaxis is typically obtained with doses not exceeding 200 mg daily. Alternate-day dosing regimens can also be effective. Plasma Complement 1 ( esterase ) inhibitor (C1 INH) and C4 levels rise with therapy but need not normalize totally for disease control to be achieved.
Off-Label Dermatologic Uses
Other Dermatoses
Taking advantage of their fibrinolytic properties, the attenuated androgens have been shown to relieve the pain and heal the cutaneous ulcerations of cryofibrinogenemia, improve the spectrum of lipodermatosclerosis, and effectively treat livedoid vasculopathy.
The use of attenuated anabolic steroids has been reported in lichen sclerosus et atrophicus, chronic urticaria, Raynaud phenomenon, autoimmune progesterone dermatitis, and refractory pruritus associated with myeloproliferative disorders. It is of interest that danazol has been used for the treatment of fibrocystic breast disease, endometriosis, and notably as an adjunct to surgical excision in cases of cutaneous endometriosis.
Adverse Effects
AE of attenuated androgens are related to dose and duration of therapy. Virilizing AE can be problematic in women, as can exacerbation of symptomatic prostatic hypertrophy in men. Q40.2 Muscle cramps, myalgias, elevations in serum creatine phosphokinase, microscopic hematuria, and hemorrhagic cystitis have been reported; myopathy and rhabdomyolysis with concurrent use of lipid-lowering statin drugs is a potential concern. Insulin resistance and mild deterioration of glucose tolerance may occur. Episodes of anxiety, tremulousness, and exacerbations of underlying migraine headaches have been described. Sodium-retaining properties can worsen hypertension and cause congestive heart failure, and lipid profiles can be negatively altered. Interaction with warfarin necessitates close monitoring of the international normalized ratio (INR).
Monitoring Guidelines
Because of risks of cholestatic jaundice, peliosis hepatis, and liver tumors caused by danazol, monitoring of liver function is advised. Mild elevations in hepatocellular enzymes are often transient and typically return to normal with dose reduction. If hepatotoxic effects do develop, switching therapy to oxandrolone, an anabolic steroid, reported to be less hepatotoxic and proven effective in isolated cases of lipodermatosclerosis and childhood hereditary angioedema, may be considered. Because of possible interference with normal sexual development, these drugs should be used cautiously in childhood and should not be used during pregnancy.
Biotin
Biotin (also known as vitamin H , vitamin B 7 , and coenzyme R ) is a water-soluble, B-complex vitamin, essential for the function of a number of carboxylase enzymes. Biotin serves as a cofactor for five carboxylase enzymes that catalyze steps in the metabolism of fatty acids, glucose, and amino acids, including amino acids used in keratin production. Food sources of biotin include organ meats, egg yolk, milk, fish, and nuts; biotin may also be synthesized by intestinal flora. Biotin is readily available as a supplement without a prescription. Dietary deficiency of biotin is rare. More frequently, deficiencies have been reported in association with total parenteral nutrition. Cutaneous signs of biotin deficiency are similar to those of multiple carboxylase deficiency, namely thinning of the hair and poliosis. A seborrheic dermatitis-like eruption may occur around the eyes, nose, and mouth, mimicking the rash seen in zinc deficiency.
The practicing physician is unlikely to encounter a patient with true biotin deficiency. When diagnosed, response to biotin supplementation is rapid. Q40.3 Although signs of biotin deficiency include hair loss, there is no evidence from large-scale studies to support the use of biotin supplements to treat these conditions in the nondeficient patient. The treatment of nail disorders is better studied with improvement reported for brittle nails, triangular worn-down nails, trachyonychia, and habit-tic nail deformity (at doses ranging from 2.5–9.5 mg/day). Biotin has been used with reported success in the treatment of atopic dermatitis, uncombable hair syndrome, and Unna-Thost syndrome. Many physicians recommend supplementation for patients’ subjective concerns of thinning or brittleness of the hair, with anecdotal success.
The daily requirement of biotin for an adult is between 30 and 100 μg. The most frequently used dose for hair and nail problems is 2.5 to 3.0 mg daily. Higher doses have been used to treat dermatitic eruptions (5 mg daily) and keratodermas (50 mg daily). Duration of therapy ranges from several weeks to months. Time to response is variable, and supplementation must be continued indefinitely to maintain improvement.
Toxicity caused by biotin intake has not been reported to date (likely in large part because of biotin being water soluble), but gastrointestinal (GI) irritation has been a rare concern. Controlled studies remain necessary to truly determine the clinical utility of biotin. The FDA issued a warning that consumption of biotin might significantly interfere with laboratory tests, including troponin levels, thyroid-stimulating hormone, N-terminal probrain natriuretic peptide, parathyroid hormone and free triiodothyronine. Patients and clinicians should be made aware of the need to discontinue biotin before biotin-streptavidin-based immunoassay tests, or to interpret the results with caution if patient was taking biotin at the time of the assay.
Clofazimine
Clofazimine (Lamprene or B663) is the most active antimycobacterial riminophenazine dye known. This class of agent was developed in 1944, as the result of an effort to chemically imitate diploicin, which is a compound that occurs naturally in lichens, and had demonstrated the ability in vitro to inhibit Mycobacterium tuberculosis . In clinical trials, clofazimine proved more effective in treating leprosy than tuberculosis, and this is still the drug’s major clinical use. Given this drug’s antimicrobial and anti-inflammatory properties, however, it has been used in a number of dermatologic conditions. Clofazimine has been successfully used to treat infectious, inflammatory, and granulomatous diseases of the skin.
Pharmacology
See Table 40.2 for key pharmacologic concepts of clofazimine. Under normal conditions, clofazimine, C 27 H 22 Cl 2 N 4 , is deep red-to-orange in color. Chemically, it belongs to the group of phenazine molecules known as riminophenazines , distinguished by substitution on the N2, N3, and C7 positions. It is most commonly synthesized today by the reduction of anilinoaposafranines.
Table 40.2
Key Pharmacology Concepts—Miscellaneous Systemic Drugs
| Absorption and bioavailability | Elimination | |||||
|---|---|---|---|---|---|---|
| Drug Name | Peak Levels | Bioavailable (%) | Protein Binding | Half-Life | Metabolism | Excretion |
| Glycopyrrolate | 5 hours | 10–25 | No data | ∼1.7 hours | Minimal | Renal and biliary, most excreted as unchanged drug |
| Oxybutynin | 1 hour | 1.6–10.9 | No data | 2–3 hours | Hepatic | Extensively metabolized by liver, less than 0.1% excreted in urine |
| Danazol | 2–8 hours | No data | No data | 9–10 hours | Significant first-pass metabolism | No data |
| Clofazimine | 1–6 hours a | 20–70 | Negligible | 70 days b | Hepatic | Small amounts in urine, smaller amounts in sebum, sweat, tears |
| Colchicine | 30–60 min | 24–88 | Minimal | 20 min c | Hepatic | Majority through bile in the feces, 10%–20% eliminated in urine unchanged |
| Penicillamine | 1–3 hours | 40–70 | ∼80% | 1–3 hours | Hepatic | Renal ≫ fecal |
| Thalidomide | 2–6 hours | 67–93 | No data | 9 hours | Nonenzymatic hydrolytic cleavage | Predominantly nonrenal, precise mechanism unknown |
| Gabapentin | 3 hours | Bioavailability of gabapentin is approximately 60, 47, 34, 33, and 27% following 900, 1200, 2400, 3600, and 4800 mg/day given in 3 divided doses, respectively | Less than 3% | 5–7 hours | Renal | Renal excretion as unchanged drug |
| Pregabalin | 1.5 hours | >90 | Does not bind to plasma proteins | 6.3 hours | Renal | Renal excretion as unchanged drug |
A number of drugs discussed in this chapter have virtually no pharmacokinetic data available and are not included in this table, this includes biotin, nicotinamide, potassium iodide, vitamin E, and zinc sulfate.
a After steady state is obtained—approximately 70 days.
b With long course of therapy—when a short course is given half-life is about 7 days.
The absorption of clofazimine after oral intake is variable. When taken with food, absorption is increased. The drug is highly lipophilic and concentrates in lipid-rich tissues, particularly within the reticuloendothelial system, but also in the breasts, intestines, and liver. Because of this, the drug is eliminated slowly, with a half-life of approximately 70 days. There have been three proposed routes of hepatic metabolism, the clinical relevance of which is unknown. Only small amounts of the drug are found in urine. Minimal, but clinically significant, elimination occurs via the sebum, sputum, tears, and sweat. Formal studies of fecal/biliary elimination have not been carried out.
Mechanism of Action
Antimicrobial Effects
See Table 40.3 for drug mechanisms and clinical correlates for clofazimine. To date, there is no single theory to fully explain clofazimine’s antimicrobial effects. In vitro, clofazimine selectively binds to deoxyribonucleic acid (DNA) guanine residues, which are in higher concentration in mycobacteria than in humans. Whether this explains its in vivo activity is uncertain. Other proposed mechanisms of action involve the drug’s inhibition of the mitochondrial respiratory chains and inhibition of the increased production of free radicals within various cell lines. Recent in vitro work has shown that the antimycobacterial effects of clofazimine can be augmented by interferon (IFN)-γ or tumor necrosis factor (TNF)-α in certain circumstances. Perhaps cytokine-enhanced clofazimine therapy will someday be a reality for the treatment of human mycobacterial infections.
Table 40.3
Drug Mechanisms—Thalidomide and Clofazimine
| Drug Name | Mechanism | Resultant Clinical Effects |
|---|---|---|
| Thalidomide | 1 Hypnosedative 2 Immunomodulatory/anti-inflammatory effect a 3 Effects on neural tissue 4 Effects on vascular tissue 5 Mechanism for teratogenicity is unknown 6 Mechanism for peripheral neuropathy is unknown |
Erythema nodosum leprosum therapy (Mech.1, 2) Cutaneous lupus erythematosus therapy (Mech. 2) Stomatitis/Behçet disease therapy (Mech. 2) Prurigo nodularis/actinic prurigo therapy (Mech. 1, 2, 3) Kaposi sarcoma (Mech. 4) |
| Clofazimine | 1 Antimicrobial effects 2 Anti-inflammatory effects 3 Selective immunomodulation 4 Lipophilicity of drug and deposition of metabolites in crystalline form |
Leprosy/atypical mycobacterial infection therapy (Mech. 1, 2, 3) Chronic cutaneous lupus erythematosus therapy (Mech. 2, 3) Pyoderma gangrenosum therapy (Mech. 2, 3) Hyperpigmentation: because of deposition of clofazimine, as well as stimulated hypermelanosis (Mech. 4) Xerosis and possible progression to ichthyosis (Mech. unknown) Abdominal pain, transient gastrointestinal disturbances; rarely splenic infarction (Mech. 4) Possible cardiotoxicity (Mech. unknown) |
a Through inhibition of tumor necrosis factor-α release and activity.
Immunological Effects
Within the immune system, clofazimine exerts its effects mainly by altering the functions of monocytes and neutrophils (polymorphonuclear neutrophil [PMN]). Among other effects on monocytes, the drug has been shown to increase the size and number of lysosomes and phagolysosomes. PMN motility and lymphocyte transformation are inhibited in a dose-dependent manner, and superoxide production is enhanced. Although phospholipase A 2 production is also enhanced, the overall effect of the drug is usually anti-inflammatory.
Clinical use
Us Food and Drug Administration-Approved Indications
Leprosy and Other Mycobacterial Infections
Clofazimine is approved for the treatment of lepromatous leprosy. It has also been used in the treatment of erythema nodosum leprosum (ENL). For multibacillary leprosy, combination drug therapy has been advocated as initial therapy to reduce the development of drug resistance. The drug has been used extensively in combination with dapsone and rifampin. Most commonly, 50 mg of clofazimine is taken daily along with an additional bolus of 300 mg monthly for at least 2 years. Different amounts of dapsone and rifampin have been recommended for concurrent use during this clofazimine course of therapy. It has been suggested that the addition of ofloxacin to this regimen may reduce the duration of therapy. In addition to leprosy, clofazimine has been used to treat tuberculosis and selected atypical mycobacterial infections.
Off-Label Dermatologic Uses
Inflammatory Skin Diseases
Within the realm of inflammatory diseases, multiple reports discuss the use of clofazimine in the treatment of pyoderma gangrenosum (PG), in both its classic and malignant forms. Small series and case reports exist to support a trial of clofazimine in a number of other inflammatory, granulomatous, and infectious processes. The likelihood of successful therapeutic outcome, as gauged by response and remission rates, is highly variable. Although clofazimine is used for a host of dermatoses, it does not appear to be the drug of choice for any one condition.
Clofazimine is seldom used as a solitary agent, but most often in combination with other antimicrobial or anti-inflammatory drugs. It does not affect the bioavailability of dapsone. It slightly alters the pharmacokinetics of rifampin, and its levels in urine and plasma are slightly elevated with simultaneous isoniazid use; the clinical significance of these alterations is presumed negligible. Usually 50 to 300 mg is given daily; doses as high as 400 mg daily have been reported by some authors. Larger doses are usually divided 3 to 4 times daily. Attempts to taper the drug to a maintenance dose should be made after clinical response occurs.
Adverse Effects
Cutaneous Effects
Clofazimine is usually safe and well tolerated. Q40.4 The most common AE, seen with its use, is a reversible orange-brown discoloration of the skin, beginning within 2 to 4 weeks of initiating use. The cause is not only direct drug deposition but is also because of an induced hypermelanosis. Tears, sweat, hair, sputum, milk, urine, and feces can also have this discoloration. This usually resolves spontaneously within a few months of stopping therapy. Approximately 30% of patients experience a generalized xerosis, although progression to frank ichthyosis is not uncommon.
Systemic Effects
Q40.4 Rare and more serious AE can result from crystal deposition within the viscera. This usually occurs in a dose- and duration-dependent manner. Deposition within the small bowel may rarely cause a fatal enteropathy. Splenic infarction and eosinophilic enteritis have also been reported. There is one case report of cardiac dysrhythmia related to clofazimine use and a pre-existing electrolyte disturbance. Common effects of less significance include abdominal cramping, nausea, and diarrhea. Nail changes, pedal edema, and exacerbation of vitiligo have also been reported.
Drug Interactions
There are relatively few drug interactions involving clofazimine. A degree of caution is encouraged for concomitant use with either rifampin or isoniazid; these interactions are of relatively low risk. Note that the concomitant use of dapsone with clofazimine is acceptable.
Monitoring Guidelines
The drug is absolutely contraindicated for those with sensitivity to clofazimine. It is relatively contraindicated during pregnancy (category C) and lactation, and for patients with pre-existing GI disease or individuals prone to electrolyte disturbances. Monitoring should focus on GI symptomatology.
Patients receiving doses in excess of 100 mg daily should have liver function tests evaluated periodically. Baseline electrolyte panels may be prudent.
Continuing evaluation of skin discoloration and its possible psychological effects on the patient may also be necessary.
Colchicine
Colchicine is an alkaloid extracted from seeds and tubers of the plant Colchicum autumnale. It has been used for centuries to treat acute gout and is the drug of choice to prevent attacks and associated amyloidosis in familial Mediterranean fever (FMF). More recently, colchicine’s anti-inflammatory properties are proving cardioprotective and show promise in managing disorders of the pericardium, myocardium and coronary arteries. In dermatology, colchicine is frequently used to treat diseases characterized by PMN infiltration.
Pharmacology
Colchicine has the chemical formula C 22 H 25 O 6 N ( Fig. 40.1 ). Peak plasma levels are reached 30 to 120 minutes after oral administration. The terminal half-life is long at 20 to 40 hours. The drug is metabolized in the liver, with the majority eliminated through bile in the feces, and 10% to 20% of the dose eliminated unchanged in the urine. Dose reduction is recommended in the setting of severe renal or hepatic impairment. Clearance and volume of distribution are reduced in the elderly, resulting in higher plasma concentrations. Thus, to decrease the risk of toxicity, lower doses may be warranted in those over 70 years of age. Colchicine must be shielded from ultraviolet (UV) light, which degrades the drug into therapeutically inactive products.
Mechanism of Action
Q40.5 Colchicine concentrates in leukocytes, at 3 times the level found in lymphocytes, and persists for several days after ingestion. It binds to the dimers of tubulin, preventing their assembly into microtubules. This results in mitotic arrest at metaphase and interference with cell motility and chemotaxis. Colchicine interferes with lysosomal degranulation, and likely because of effects on E-selectin and L-selectin, reduces PMN adhesiveness to endothelial cells. The drug is thus both antimitotic and anti-inflammatory. The anti-inflammatory properties of colchicine are notably selective and not observed in all diseases with upregulated neutrophilic activity. Specifically, colchicine has been shown to inhibit inflammasome-mediated interleukin (IL)-1β, which may account for its efficacy in treating IL-1–mediated diseases, including FMF. Colchicine binds to cytochrome P3A4 (CYP3A4) and P-glycoprotein (P-gp), which are responsible for its metabolism, as well as many drug interactions. Inadequate response to colchicine may be caused by overexpression of these proteins. Dosage adjustment of colchicine is warranted in the setting of multiple coadministered drugs.
Clinical Use
Box 40.1 lists indications for colchicine, whereas Box 40.2 presents the risks profile for colchicine.
Box 40.1
Colchicine Indications
IgA , Immunoglobulin A.
| US Food and Drug Administration-Approved Indications | |
| None Specific to Dermatology | |
| Off-Label Dermatologic Uses | |
Neutrophilic dermatoses/bullous dermatoses
Vasculitis
Papulosquamous dermatoses
|
Autoimmune connective tissue diseases
Other dermatoses
|
Box 40.2
Drug Risks Profile—Colchicine
Data from Facts & Comparisons eAnswers (online database). St. Louis: Wolters Kluwer. ( https://www.wolterskluwercdi.com/facts-comparisons-online/ ).
CKD, Chronic kidney disease CYP , cytochrome P-450; GI , gastrointestinal.
| Contraindications | |
|
|
| Boxed Warnings | |
|
|
| Warnings & Precautions a | |
Overdose
Hematologic
|
Neuromuscular
GI
|
| Pregnancy Prescribing Status | |
|
|
a Under “Warnings & Precautions” these adverse effects can be considered relatively high risk or important clinical scenarios to avoid.
b See Chapter 65 , Dermatologic Drugs During Pregnancy and Lactation, for detailed explanations of terms for “Newer rating” based on 2015 US Food and Drug Administration rulings.
Off-Label Dermatologic Uses
Neutrophilic Dermatoses
Colchicine’s value in the treatment of acute gouty arthritis and FMF is well established, including a 2009 FDA approval (Colcrys) for flares of acute gout. Use in the treatment of Behçet disease, a predominantly neutrophilic dermatosis, is also fairly well established. Although conflicting studies exist, improvement has been documented in the oral, genital, and ocular lesions of Behçet disease, as well as in associated erythema nodosum and articular complaints.
The PMN inflammatory infiltrate and enhanced leukocyte chemotaxis of Behçet disease are also seen in recurrent aphthous stomatitis where colchicine has also proven efficacious. Colchicine has shown utility in treating Sweet syndrome and case reports suggest it may be useful in treating dermatitis herpetiformis, linear immunoglobulin A (IgA) bullous dermatosis, in both children and adults, IgA pemphigus, and epidermolysis bullosa acquisita.
Vasculitis
The use of colchicine in the treatment of cutaneous leukocytoclastic vasculitis is controversial. One prospective, randomized controlled trial (RCT) showed no significant therapeutic effect with colchicine compared with placebo, but identified several patients who cleared with colchicine and relapsed with its discontinuation. Many uncontrolled reports advocate use of colchicine for treating chronic cutaneous leukocytoclastic vasculitis, citing a majority of patients achieving complete disease control or being able to taper their concurrent corticosteroid (CS) dose. A beneficial effect on the associated arthritis has also been observed. One case report describes resolution of chronic cryofibrinogenemia-related lower extremity ulcerations when colchicine was added to an unsuccessful regimen of high-dose pentoxyfylline.
Papulosquamous Dermatoses
Colchicine, with its PMN suppression and antimitotic activity, could theoretically be beneficial in treating psoriasis and palmoplantar pustulosis. In some patients, favorable results have been observed, although this therapy is considered a nonstandard option at best. Colchicine may be most effective for thin psoriatic lesions and as maintenance therapy after remission is obtained through other treatment modalities.
Other Dermatoses
Colchicine’s suppression of local inflammation caused by calcinosis in dermatomyositis and progressive systemic sclerosis (PSS) has been reported. Prolonged colchicine therapy, however, has not been shown to halt disease progression in PSS. Anecdotal reports suggest that colchicine may be efficacious for other diseases, including relapsing polychondritis, pachydermoperiostosis, with acro-osteolysis, and mild to moderate type II lepra reactions. In a single case, the inflammatory component of primary anetoderma responded to colchicine. Several studies have shown topical colchicine to effectively treat actinic keratoses, as well as condylomata acuminata.
Adverse Effects
Box 40.2 summarizes the drug risks profile for colchicine.
Gastrointestinal Effects
The dose for dermatologic conditions is typically 0.6 mg 2 or 3 times daily, subsequently tapered as disease activity allows. Q40.6 For some patients, tolerance is enhanced by starting at once-daily therapy and gradually increasing the frequency over a number of weeks. Therapeutic doses of colchicine alter both jejunal and ileal function, such that abdominal cramping, hyperperistalsis, and watery diarrhea often occur with thrice-daily dosing. Diarrhea can be controlled with aluminum-containing antacids (Amphojel, Alternajel) or specific oral antidiarrheal medications, such as loperamide.
Drug Interactions
Table 40.4 lists drug interactions for colchicine. Colchicine dosage should be reduced as much as 33% to 66%, when coadministered with CYP3A4- and P-gp–inhibiting drugs. Drugs that interact with both of these metabolic pathways, specifically clarithromycin, azole antifungals, protease inhibitors, verapamil and diltiazem, carry high risk for drug toxicity. The strong P-gp inhibitor cyclosporine also poses significant risk for colchicine toxicity. The risk of myopathy may be increased when colchicine is taken with a statin.
Table 40.4
Drug Interactions—Colchicine
Data from Facts & Comparisons eAnswers (online database). St. Louis: Wolters Kluwer. ( https://www.wolterskluwercdi.com/facts-comparisons-online/ ); Hansten PD, Horn JR. The Top 100 Drug Interactions: a Guide to Patient Management , 2019 Edition. Freeland, WA: H&H Publications, 2019. ( http://www.hanstenandhorn.com/ ).
| Drug Category | Drug Examples | Comments |
|---|---|---|
| Relatively High-Risk Drug Interactions a | ||
| Statins | Simvstatin, atorvastatin, lovastatin | CYP3A4 substrates may have greater risk of myopathy/rhabdomyolysis than other statins |
| Fibrates | Fenofibrate, gemfibrozil | Gemfibrozil CYP3A4 substrate (fenofibrate not) both may ↑ risk of myopathy/rhabdomyolysis |
| Macrolides/azalides | Erythromycin > clarithromycin >> azithromycin | Combined strong CYP3A4 inhibitors and p-glycoprotein inhibitors ↑ colchicine serum levels, toxicity |
| Azoles/triazoles | Ketoconazole > itraconazole >> fluconazole (only doses >200 mg) | same |
| Calcium-channel blockers | Diltiazem , verapamil | same |
| Calcineurin inhibitors | Cyclosporine , tacrolimus (oral) | same |
| Foods | Grapefruit juice | same |
| Inotropic agents | Digoxin | May ↑ colchicine serum levels, uncertain mechanism |
| HIV meds | Fosamprenavir | same |
| Lower-Risk Drug Interactions | ||
| Vitamins | Cyanocobalamin (B12) | Colchicine may ↓ serum concentrations cyanocobalamin and folate (also fat soluble vitamins A, D, E) |
| Minerals | Iron | Colchicine may ↓ serum concentration of iron, risk anemia |
CYP , Cytochrome P-450; HIV , human immunodeficiency virus.
a Overall highest-risk drug interactions indicated in bold italics.
Colchicine Overdose
The therapeutic index of colchicine is narrow, generally between 0.015 and 0.03 mg/kg, with doses greater than 0.8 mg/kg being predictably fatal. Overdose can lead to a cholera-like syndrome with dehydration, hypokalemia, hyponatremia, metabolic acidosis, renal failure, and ultimately shock. Respiratory distress syndrome, disseminated intravascular coagulation, and bone marrow failure may ensue. Other toxic manifestations include hepatic failure and late central nervous system (CNS) disorders. Myopathy, hypocalcemia, alopecia, stomatitis, and porphyria cutanea tarda have been reported in acutely intoxicated patients, who ultimately survived.
Chronic intoxication may uncommonly occur after prolonged therapy with at least 1 mg daily. Complications include leukopenia, aplastic anemia, myopathy, and alopecia. Azoospermia and megaloblastic anemia, secondary to vitamin B 12 malabsorption, have also been described.
Treatment is supportive. Intravenous colchicine carries serious risk, including death and is no longer available in the United States.
Use in Pregnancy and Lactation
In otherwise healthy women, colchicine use during pregnancy has been associated with lower birthweight and lower gestational age. It is classified as pregnancy Category C. However, to prevent disease relapse in women with FMF and Behçet, the literature strongly supports the ongoing use of colchicine throughout pregnancy. In these settings, studies have shown no increase in fetal malformations or miscarriages. The American Academy of Pediatrics classifies colchicine as compatible with breastfeeding, in which case it should be taken immediately after nursing.
Monitoring Guidelines
Monitoring should be individualized with special consideration for overall health status and coadministered medications. Complete blood counts (CBC), platelet count, serum multiphasic analysis, and urinalysis should be performed at least every 3 months. Monthly laboratory monitoring for the first few months of therapy is reasonable.
Fumaric Acid Esters
Fumaric acid esters (FAE) have been used for the treatment of psoriasis for decades. Used primarily in Europe, especially Germany, the medication is not currently available in the United States. The oral preparations used are usually mixtures of esters. It is unclear whether there is a single active component within these mixtures or whether additive or synergistic effects are at work.
FAE appear to be modestly active against psoriasis in controlled studies, with fewer serious AE than many other medications used to treat this disease. Commonly reported AE include flushing and GI problems. More severe AE are reported less commonly.
Niacinamide
Pharmacology
Nicotinic acid (niacin, vitamin B 3 ) is an essential dietary constituent, the deficiency of which leads to pellagra. In the body, nicotinic acid (niacin) is converted to niacinamide (nicotinamide), which functions as a crucial coenzyme that accepts hydrogen ions in oxidation-reduction reactions essential for tissue respiration; it is a necessary cofactor for adenosine triphosphate (ATP) production. Both nicotinic acid and niacinamide are readily absorbed from the GI tract and distributed to all tissues.
Mechanism of Action
Q40.7 Several mechanisms have been proposed to explain the anti-inflammatory effect of niacinamide. Niacinamide inhibits poly-(adenosine) diphosphate-ribose polymerase-1 (PARP-1), a nuclear enzyme that enhances nuclear factor-κB transcription. Inhibition of this pathway alters leukocyte chemotaxis by dysregulation of adhesion factors necessary for migration. Niacinamide reduces lysosomal enzyme release and stabilizes leukocytes by inhibiting cyclic adenosine monophosphate phosphodiesterase (cAMP PDE), and also inhibits lymphocytic transformation and the production of antibodies. This latter mechanism makes the drug particularly useful for the treatment of antibody-mediated diseases (e.g., bullous pemphigoid). Other reports show niacinamide to be effective in inhibiting mast cell degranulation, thereby preventing the release of vasoactive amines, such as histamine and eosinophil chemotactic factor, and providing yet another useful mechanism for the treatment of bullous pemphigoid.
Topical niacinamide retains these anti-inflammatory effects, making it a potentially useful adjunct treatment for acne. It also stabilizes epidermal barrier function through a reduction in transepidermal water loss, increases protein (e.g., keratin) and ceramide production in the stratum corneum, speeds up keratinocyte differentiation, and inhibits the transfer of melanosomes from melanocytes to keratinocytes, all of which make it an attractive topical therapy to fight the cutaneous signs of aging.
More recently, niacinamide has been shown to possess chemoprevention properties. Specifically by preventing ATP depletion and glycolytic blockade, niacinamide promotes DNA repair and reduces immunosuppression caused by UV radiation.
Clinical Use
Off-Label Dermatologic Uses
Overall Dermatologic Uses
Niacinamide can be used for prophylaxis and treatment of pellagra caused by poor nutrition, Hartnup disease, or carcinoid tumors. Of most interest, however, is niacinamide’s reported utility in treating autoimmune bullous dermatoses, including the full spectrum of pemphigoid, pemphigus, dermatitis herpetiformis, and linear IgA dermatosis. Anecdotally, it has also been used to treat erythema elevatum diutinum, polymorphous light eruption, granuloma annulare, and necrobiosis lipoidica. Systemic niacinamide, in combination with azelaic acid, folic acid, copper, and pyridoxine, has also been marketed as a prescription dietary supplement, useful in the management of acne vulgaris.
Purported uses for topical niacinamide include improved epidermal barrier function and keratinocyte differentiation to fight signs of aging, improvement of isoniazid-induced pellagra-like skin lesions, improvement in wound healing, and anti-inflammatory and sebosuppressive effects useful in the treatment of acne vulgaris and rosacea. Topical niacinamide has also been shown to reduce the immunosuppressive effects of UV irradiation, making it an attractive additive in topical sunscreen preparations. Similarly, by reducing cutaneous immunosuppression, impeding cellular energy depletion, and promoting DNA repair, oral niacinamide has found a niche as a chemopreventive agent for nonmelanoma skin cancers.
Bullous Dermatoses
One randomized, open-label trial suggested comparable efficacy and fewer AE using the combination of niacinamide and tetracycline, compared with prednisone as first-line therapy for bullous pemphigoid. Another small review suggested that the combination of niacinamide and tetracycline derivatives may be an effective alternative to CS in pemphigus foliaceus and pemphigus erythematosus and a CS-sparing adjuvant, rather than CS alternative in pemphigus vulgaris. A more recent retrospective review of 51 patients with a spectrum of pemphigus also concluded that this combination therapy may be useful as ‘CS-sparing-sparing therapy’. Assessment of clinical response to niacinamide alone, in treating autoimmune blistering disorders and erythema elevatum diutinum, has clearly been complicated by concomitant tetracycline or erythromycin use in these studies. It has been proposed that the anti-inflammatory properties of these antibacterial agents may function synergistically with niacinamide in the treatment of diseases with excessive PMN chemotaxis. Because tetracycline alone has been reported to clear bullous pemphigoid, it is difficult to assess niacinamide’s exact contribution in treatment of bullous diseases. However, one case of localized bullous pemphigoid responding to niacinamide alone has been reported.
Skin-Cancer Chemoprevention
In a double-blind, randomized, controlled trial of 386 immunocompetent participants at high risk for skin cancer, niacinamide reduced rates of new basal cell carcinomas by 20% and new squamous cell carcinomas by 30%. Research suggests niacinamide might serve a similar role in preventing arsenic-induced skin cancers. Although more studies are warranted, enthusiasm exists for the chemopreventive use of nicotinamide in patients at high risk for skin cancer, particularly in the setting of renal transplantation.
Photodermatoses
Some researchers believe that niacinamide has a beneficial effect in the prevention of polymorphous light eruption. However, using phototesting, others failed to document this favorable response.
Dosing Strategies
In the treatment of autoimmune bullous diseases and granulomatous diseases, the dose of niacinamide has averaged 500 mg, 3 times daily. Four times daily dosing may also be considered. The concurrent tetracycline dose has typically been 500 mg, 4 times daily, although lower doses have proved to be efficacious. Minocycline 100 mg twice daily has been substituted in patients with GI distress attributed to tetracycline. There is also significant clinical experience combining niacinamide with doxycycline 100 mg twice daily. For chemoprevention purposes, the studied dose of niacinamide has been 500 mg twice daily.
Adverse Effects
Niacinamide is considered a very safe medication with few AE. Box 40.3 outlines the drug risks profile for niacinamide. Extensive information regarding AE is available through the older literature on schizophrenia, for which the drug was used in doses of 3 to 12 g daily. Headache and GI complaints occasionally occur. Hepatotoxicity is considered extremely rare but may justify the monitoring of liver function tests in patients receiving long-term, high-dose therapy. Whereas nicotinic acid (niacin) is a potent vasodilator, niacinamide is not, and thus is not typically associated with flushing and other prostaglandin-triggered AE.
Box 40.3
Drug Risks Profile—Niacinamide
Data from Facts & Comparisons eAnswers (online database). St. Louis: Wolters Kluwer. ( https://www.wolterskluwercdi.com/facts-comparisons-online/ ).
OTC , Over the counter.
| Contraindications | |
|
|
| Boxed Warnings | |
|
|
| Warnings & Precautions a | |
|
|
| Pregnancy Prescribing Status | |
|
|
a Under “Warnings & Precautions” these adverse effects can be considered relatively high risk or important clinical scenarios to avoid.
b See Chapter 65 , Dermatologic Drugs During Pregnancy and Lactation, for detailed explanations of terms for “Newer rating” based on 2015 US Food and Drug Administration rulings.
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