Itraconazole

Itraconazole is a broad spectrum triazole antifungal agent. It has favourable pharmacodynamic and pharmacokinetic profiles and is available as both oral and i.v. formulations. Over the last two decades, clinical and animal infection studies have demonstrated the efficacy of itraconazole in a wide range of superficial fungal infections including difficult-to-treat dermatophytoses and onychomycoses. Furthermore, shortened treatment regimens have proven to be effective, ranging from 1-day treatment for vaginal candidosis to 1-week pulse therapy per month, for 2-4 months, in onychomycosis and follicular dermatophytosis. Clinical experience with itraconazole in the treatment of deep mycoses is less comprehensive. However, results in systemic candidosis, sporotrichosis, blastomycosis, paracoccidioiodomycosis, certain types of histoplasmosis and aspergillosis are extremely encouraging. Itraconazole is less effective in the treatment of chromomycosis and coccidioidomycosis. Nevertheless, considering the refractory nature of these diseases, itraconazole has proven to be a valuable addition to the antifungal drugs currently available for treatment. Itraconazole has been well-tolerated with doses of up to 400 mg/day being generally free of serious adverse effects. However, a potential for drug interactions exists, mediated through the cytochrome P450 enzyme 3A4 system, which should be considered when itraconazole is used as part of a multi-drug regimen.     

Impact of Absolute Stereochemistry on the Antiangiogenic and Antifungal Activities of Itraconazole

Itraconazole is used clinically as an antifungal agent and has recently been shown to possess antiangiogenic acitivity. Itraconazole has three chiral centers that give rise to eight stereoisomers. The complete role of stereochemistry in the two activities of itraconazole, however, has not been addressed adequately. For the first time, all eight stereoisomers of itraconazole (1a-1h) have been synthesized and evaluated for activity against human endothelial cell proliferation and for antifungal activity against five fungal strains. Distinct antiangiogenic and antifungal activity profiles of the trans- stereoisomers, especially 1e and 1f, suggest different molecular mechanisms underlying the anti-angiogenic and anti-fungal activities of itraconazole.     

Itraconazole: pharmacology, clinical experience and future development

Itraconazole is an orally active, broad-spectrum, triazole antifungal agent which has a higher affinity for fungal cytochrome P-450 than ketoconazole but a low affinity for mammalian cytochrome P-450. Itraconazole has a broader spectrum of activity than other azole antifungals and shows interesting pharmacokinetic features in terms of its tissue distribution. These properties have resulted in reduced treatment times for a number of diseases such as vaginal candidiasis, as well as effective oral treatment of several deep mycoses, including aspergillosis and candidiasis. Currently itraconazole is registered in 42 countries for the treatment of systemic fungal infections. Further development is concentrating on antifungal prophylaxis as well as on an oral solution and an intravenous formulation.     

Itraconazole solution: summary of pharmacokinetic features and review of activity in the treatment of fluconazole-resistant oral candidosis in HIV-infected persons.

The clinical pharmacology of itraconazole is presented in relation to its use in the treatment of fluconazole-resistant oropharyngeal candidosis. The oral solution is a new formulation of itraconazole in which itraconazole is solubilised with the use of cyclodextrin. This formulation has a higher bioavailability and leads to higher local concentrations in the oral cavity which are advantages over the solid capsule formulation. Literature, in which the use of itraconazole oral solution was described to treat fluconazole-resistant oral candidosis, is reviewed. In about 55% of the patients signs and symptoms of oral candidosis were resolved after treatment with itraconazole oral solution. Although all the reviewed studies lack data to objectively qualify all the included patients as having a fluconazole-resistant candidosis, the authors conclude, that based on the available information itraconazole oral solution 100 or 200mg twice daily can be effective for fluconazole-resistant oropharyngeal candidosis (OPC) and should be considered prior to salvage therapy with intravenous amphotericin B. The use of itraconazole, however, requires careful monitoring of the patients co-medication for potential serious drug-drug interactions.     

Clinical pharmacokinetic monitoring of itraconazole is warranted in only a subset of patients

Itraconazole is a synthetic triazole antifungal agent that is commonly used in the prophylaxis and treatment of fungal infection. A role for itraconazole drug monitoring has been suggested previously; however, the advent of new formulations and increased clinical evidence may aid in further defining this role. Consequently, we have used a previously published decision-making algorithm to determine whether clinical pharmacokinetic monitoring of itraconazole is warranted. First, itraconazole has proven efficacy for the prophylaxis and treatment of fungal infection in immunocompromised individuals such as neutropenic cancer, human immunodeficiency virus (HIV), and solid organ transplant patients. Several assays have been developed to quantify itraconazole and its main metabolite in patient plasma. Measurement of these plasma drug levels in many clinical studies has resulted in no clear definition of a relationship between concentration and efficacy. However, limited evidence suggests a correlation between itraconazole levels greater than 250 or 500 ng/mL and increased efficacy. Clinical monitoring of efficacy is difficult because of the challenges in diagnosis of fungal infections and nonspecific clinical symptoms associated with fungal infections. Pharmacokinetic studies of itraconazole indicate that significant inter- and intrapatient variability exists in both healthy and immunocompromised patient populations, although subpopulations such as neutropenic cancer and HIV patients appear to require more drug than their healthy counterparts to attain similar drug levels. A therapeutic range has not been defined for itraconazole, but because of its relatively minimal side effects, a narrow range is unlikely. Drug interactions can occur with itraconazole because it is both an inhibitor and substrate of the cytochrome P450 3A4 (CYP3A4) enzyme and P-glycoprotein transporter systems. Protein binding alterations could also lead to differences in drug effect. Last, the duration of treatment of prophylaxis is significantly long to propose a potential benefit from drug monitoring. From weighing the available evidence, it appears that itraconazole drug level monitoring would provide more information on efficacy than clinical judgment alone in a subset of patients. Immunosuppressed patients requiring preventative therapy who have suspected poor absorption, are on concomitant enzyme inducers, or are suspected to be noncompliant would have the greatest benefit from itraconazole drug monitoring.     

A risk-benefit assessment of the newer oral antifungal agents used to treat onychomycosis.

The newer antifungal agents itraconazole, terbinafine and fluconazole have become available to treat onychomycosis over the last 10 years. During this time period these agents have superseded griseofulvin as the agent of choice for onychomycosis. Unlike griseofulvin, the new agents have a broad spectrum of action that includes dermatophytes, Candida species and nondermatophyte moulds. Each of the 3 oral antifungal agents, terbinafine, itraconazole and fluconazole, is effective against dermatophytes with relatively fewer data being available for the treatment of Candida species and nondermatophyte moulds. Itraconazole is effective against Candida onychomycosis. Terbinafine may be more effective against C. parapsilosis compared with C. albicans; furthermore with Candida species a higher dose of terbinafine or a longer duration of therapy may be required compared with the regimen for dermatophytes. The least amount of experience in treating onychomycosis is with fluconazole. Griseofulvin is not effective against Candida species or the nondermatophyte moulds. The main use of griseo-fulvin currently is to treat tinea capitis. Ketoconazole may be used by some to treat tinea versicolor with the dosage regimens being short and requiring the use of only a few doses. The preferred regimens for the 3 oral antimycotic agents are as follows: itraconazole - pulse therapy with the drug being administered for 1 week with 3 weeks off treatment between successive pulses; terbinafine - continuous once daily therapy; and fluconazole - once weekly treatment. The regimen for the treatment of dermatophyte onychomycosis is: itraconazole - 200mg twice daily for I week per month x 3 pulses; terbinafine - 250 mg/day for 12 weeks; or, fluconazole - 150 mg/wk until the abnormal-appearing nail plate has grown out, typically over a period of 9 to 18 months. For the 3 oral antifungal agents the more common adverse reactions pertain to the following systems, gastrointestinal (for example, nausea, gastrointestinal distress, diarrhoea, abdominal pain), cutaneous eruption, and CNS (for example, headache and malaise). Each of the new antifungal agents is more cost-effective than griseofulvin for the treatment of onychomycosis and is associated with high compliance, in part because of the shorter duration of therapy. The newer antifungal agents are generally well tolerated with drug interactions that are usually predictable.     

Pharmacology of itraconazole

Itraconazole is a triazole antifungal agent that has a broad spectrum of activity and is well tolerated. Itraconazole is highly efficacious, particularly because its main metabolite, hydroxy-itraconazole, also has considerable antifungal activity. The original capsule formulation of itraconazole may lead to variability in absorption and the plasma concentration. For the treatment of superficial fungal infections, this is not problematical because itraconazole accumulates at the infection site, making consistently high plasma concentrations unnecessary -- a characteristic that has been exploited in the development of a pulse regimen. Because consistent plasma concentrations are critical for the more serious systemic fungal infections, variable absorption of itraconazole from the capsules limits their application. Moreover, underlying disease processes and medical interventions can reduce absorption from the capsules in some patients with systemic fungal infections. To widen the beneficial application of itraconazole to include such patients, an oral solution and an intravenous formulation were developed. These formulations combine lipophilic itraconazole with hydroxypropyl-beta-cyclodextrin, a ring of substituted glucose molecules, which improves the solubility of itraconazole. The enhanced absorption and bioavailability of itraconazole from these new formulations make them ideal for the treatment of systemic fungal infections in a wide range of patient populations. The additional flexibility offered by the different routes of administration also means that itraconazole can be used in patients at high risk, such as children or those requiring intensive care, for whom the capsule formulation may be impractical.     

Involvement of phenobarbital and SKF 525A in the hepatotoxicity of antifungal drugs itraconazole and fluconazole in rats

Itraconazole and fluconazole are potent wide spectrum antifungal drugs. Both of these drugs induce hepatotoxicity clinically. The mechanism underlying the hepatotoxicity is unknown. The purpose of this study was to investigate the role of phenobarbital (PB), an inducer of cytochrome P450 (CYP), and SKF 525A, an inhibitor of CYP, in the mechanism of hepatotoxicity induced by these two drugs in vivo. Rats were pretreated with PB (75 mg/kg for 4 days) prior to itraconazole or fluconazole dosing (20 and 200 mg/kg for 4 days). In the inhibition study, for 4 consecutive days, rats were pretreated with SKF 525A (50 mg/kg) or saline followed by itraconazole or fluconazole (20 and 200 mg/kg) Dose-dependent increases in plasma alanine aminotransferase (ALT), gamma-glutamyl transferase (gamma-GT), and alkaline phosphatase (ALP) activities and in liver weight were detected in rats receiving itraconazole treatment. Interestingly, pretreatment with PB prior to itraconazole reduced the ALT and gamma-GT activities and the liver weight of rats. No changes were observed in rats treated with fluconazole. Pretreatment with SKF 525A induced more severe hepatotoxicity for both itraconazole and fluconazole. CYP 3A activity was inhibited dose-dependently by itraconazole treatment. Itraconazole had no effects on the activity of CYP 1A and 2E. Fluconazole potently inhibited all three isoenzymes of CYP. PB plays a role in hepatoprotection to itraconazole-induced but not fluconazole-induced hepatotoxicity. SKF 525A enhanced the hepatotoxicity of both antifungal drugs in vivo. Therefore, it can be concluded that inhibition of CYP may play a key role in the mechanism of hepatotoxicity induced by itraconazole and fluconazole.     

Econazole: a review of its antifungal activity and therapeutic efficacy.

Econazole1 is a recently introduced imidazole antifungal agent which is very closely related structurally to another imidazole derivative, miconazole. For local application the nitrate salt of econazole is used, while in preliminary investigations of systemic use in a few patients econazole base has been administered orally or intravenously. In uncontrolled studies in large numbers of patients, econazole nitrate has been administered topically in the treatment of dermatomycoses due to a wide variety of fungi, and vaginally in the treatment of vaginal candidosis; but it has not been compared with any other antifungal drug in controlled therapeutic trials in mycoses of the skin and has only been compared with nystatin in a few patients with vaginal candidosis. Until adequate comparative studies are done the relative place of econazole in the treatment of dermatomycoses and vaginal condidosis, compared with traditional antifungal agents and with other imidazole derivatives such as miconazole or clotrimazole, cannot be clearly stated. Nevertheless, econazole nitrate is an effective antifungal drug. In dermatological studies about 90% of a large number of patients were cured, often after a relatively short treatment period (2 to 6 weeks, as occurs with other imidazole antifungal agents). The cure rate was only slightly lower (about 85%) in patients with severe mycoses of many years' duration than in those whose infections were of more recent onset. In vaginal candidosis a 3-day treatment regimen using a 150mg suppository once daily was only slightly less effective (85% mycological cure rate) than a 15-day regimen using a 50mg dose (suppository or cream) once daily (90% cure rate). A 3 to 5 day 'higher' dose regimen was slightly more effective than a standard 15-day regimen of nystatin vaginal inserts in a small group of patients with vaginal candidosis. The convenience of the higher-dose shorter term regimen would likely be an important advantage to most patients. Whether other agents useful in vaginal candidosis would be as effective as econazole were they to be used in this way, has not been determined. Topical or intravaginal econazole nitrate has usually been well tolerated, side effects being limited to local irritation in about 1 to 4% of patients in most studies.     

Involvement of Phenobarbital and SKF 525A in the Hepatotoxicity of Antifungal Drugs Itraconazole and Fluconazole in Rats

Itraconazole and fluconazole are potent wide spectrum antifungal drugs. Both of these drugs induce hepatotoxicity clinically. The mechanism underlying the hepatotoxicity is unknown. The purpose of this study was to investigate the role of phenobarbital (PB), an inducer of cytochrome P450 (CYP), and SKF 525A, an inhibitor of CYP, in the mechanism of hepatotoxicity induced by these two drugs in vivo. Rats were pretreated with PB (75 mg/kg for 4 days) prior to itraconazole or fluconazole dosing (20 and 200 mg/kg for 4 days). In the inhibition study, for 4 consecutive days, rats were pretreated with SKF 525A (50 mg/kg) or saline followed by itraconazole or fluconazole (20 and 200 mg/kg) Dose-dependent increases in plasma alanine aminotransferase (ALT), γ-glutamyl transferase (γ-GT), and alkaline phosphatase (ALP) activities and in liver weight were detected in rats receiving itraconazole treatment. Interestingly, pretreatment with PB prior to itraconazole reduced the ALT and γ-GT activities and the liver weight of rats. No changes were observed in rats treated with fluconazole. Pretreatment with SKF 525A induced more severe hepatotoxicity for both itraconazole and fluconazole. CYP 3A activity was inhibited dose-dependently by itraconazole treatment. Itraconazole had no effects on the activity of CYP 1A and 2E. Fluconazole potently inhibited all three isoenzymes of CYP. PB plays a role in hepatoprotection to itraconazole-induced but not fluconazole-induced hepatotoxicity. SKF 525A enhanced the hepatotoxicity of both antifungal drugs in vivo. Therefore, it can be concluded that inhibition of CYP may play a key role in the mechanism of hepatotoxicity induced by itraconazole and fluconazole.     

Local treatment of vulvovaginal candidosis : general and practical considerations

Vulvovaginal candidosis is a common worldwide female medical problem, occurring mostly in women of childbearing age. Currently available options for the treatment of this condition include local and oral (systemic) therapy. Both alternatives have been considered equally effective in the treatment of uncomplicated vulvovaginal candidosis, although oral regimens are often preferred by physicians and women. However, local treatment presents several advantageous and unique features that may favour this therapeutic approach. The availability of numerous antifungal drugs and products for topical administration makes the selection quite challenging as this task is mostly based on personal experience or anecdotal data. Also, recent advances have been made in topical antifungal formulations and there is an increasing availability of over-the-counter products. Therefore, a review of both general and practical considerations related to the local treatment of vulvovaginal candidosis is timely.In summary, azoles and short-term regimens are usually recommended for the local treatment of vulvovaginal candidosis, with nystatin and boric acid considered as second-line alternatives. Unconventional approaches may also be regarded as suitable in patients refractory to usual treatments. In addition to the susceptibility of implicated Candida spp. to the antifungal agents, this choice should take into consideration other important issues such as particular situations (e.g. pregnancy, menopause, drug hypersensitivity), women's preferences, and the availability, particularities and cost of antifungal formulations.     

Pharmacokinetics of antifungal agents in onychomycoses

Onychomycosis is caused by infection by fungi, mainly dermatophytes and nondermatophyte yeasts or moulds; it affects the fingernails and, more frequently, the toenails. Dermatophytes are responsible for about 90 to 95% of fungal infections. Trichophyton rubrum is the most common dermatophyte; Candida albicans is the major nondermatophyte yeast. Although topical therapy of onchomycosis does not lead to systemic adverse effects or interactions with concomitantly taken drugs, it does not provide high cure rates and requires complete compliance from the patient. At present there are 3 oral antifungal medications that are generally used for the short term treatment of onychomycosis: itraconazole, terbinafine and fluconazole. The persistence of these active drugs in nails allows weekly administration, reduced treatment or a pulse regimen. Good clinical and mycological efficacies are obtained with itraconazole 100 to 200 mg daily, terbinafine 250mg daily for 3 months, or fluconazole 150 mg weekly for at least 6 months. Itraconazole is a synthetic triazole with a broad spectrum of action. It is well absorbed when administered orally and can be detected in nails 1 to 2 weeks after the start of therapy. The nail : plasma ratio stabilises at around 1 by week 18 of treatment. Itraconazole is still detectable in nails 27 weeks after stopping administration. Nail concentrations are higher than the minimum inhibitory concentration (MIC) for most dermatophytes and Candida species from the first month of treatment. The elimination half-life of itraconazole from nails is long, ranging from 32 to 147 days. Terbinafine is a synthetic allylamine that is effective against dermatophytes. Terbinafine is well absorbed from the gastrointestinal tract, and the time to reach effective concentrations in nail is 1 to 2 weeks. The half-life is from 24 to 156 days, explaining the observed persistence of terbinafine in nails for longer than 252 days. Fluconazole is a bis-triazole broad spectrum antifungal with high oral bioavailability. The uptake of fluconazole by nail increases with the length of treatment, and nail : plasma ratios are generally 1.5 to 2 at steady state. Fluconazole concentrations exceed the MIC for Candida species soon after the start of treatment. Fluconazole concentrations fall slowly after the drug is stopped, with a half-life of 50 to 87 days, and fluconazole is still detectable in nails 5 months after the end of treatment. All these drugs are potent inhibitors of cytochrome P450 (CYP) enzymes and may increase the plasma concentrations of concomitantly used drugs. Itraconazole inhibits CYP3A4. Fluconazole inhibits CYP3A4, but to a lesser degree than itraconazole, CYP2C9 and CYP2C19. Terbinafine inhibits CYP2D6.     

Terbinafine. A pharmacoeconomic evaluation of its use in superficial fungal infections

Terbinafine is an orally and topically active allylamine antifungal drug which is an effective and well tolerated therapy for a wide range of superficial dermatophyte infections. In contrast to most other commonly prescribed antifungal agents, terbinafine is fungicidal in vitro and possesses improved pharmacokinetic properties with respect to drug penetration into nail tissue following oral administration. These properties enable terbinafine to achieve high success rates with shortened therapy regimens in the treatment of dermatophyte skin infections and onychomycosis. Pharmacoeconomic analyses have shown that oral terbinafine, with its higher rates of clinical efficacy and lower rates of relapse/reinfection, is less costly and more cost effective than oral griseofulvin, ketoconazole and itraconazole when used as initial therapy in the treatment of onychomycosis. However, some points regarding the clinical efficacy of itraconazole relative to terbinafine and the drug treatment regimens used in these studies need further clarification. In the management of tinea pedis, a cost analysis suggested that initial therapy with terbinafine 1% cream was more costly than initial therapy with miconazole, oxiconazole or clotrimazole. However, in cost-effectiveness studies, terbinafine had a lower cost per disease-free day than ciclopirox, clotrimazole, ketoconazole and miconazole in the treatment of dermatophyte skin infections. In conclusion, available clinical and pharmacoeconomic data support the use of topical terbinafine as first-line treatment of dermatophyte skin infections unless the acquisition cost of terbinafine is markedly greater than that of alternative topical antifungal agents. Oral terbinafine can be recommended as a cost-effective first-line treatment, preferable to oral griseofulvin, ketoconazole and itraconazole, in patients with dermatophyte onychomycosis.     

Synthesis and in vitro and in vivo structure-activity relationships of novel antifungal triazoles for dermatology

In search for new compounds with potential for clinical use as antifungal agents in dermatology, a series of 12 azole compounds were synthesized stereospecifically and investigated specifically for their activity against dermatophyte fungal infections in animal models. This panel of azoles was studied in vitro and compared with itraconazole and terbinafine for their antifungal activity using a panel of 24 Candida spp. and 182 dermatophyte isolates. Three azoles (1c, 2c, and 4c) showed in vitro antifungal potency equivalent to itraconazole, but superior to terbinafine, against a panel of 24 Candida spp. with comparable or lower activity than that of itraconazole and terbinafine against 182 dermatophyte isolates and only rare activity against other pathogenic fungi. However, in vivo 1c and 4c, both given orally, demonstrated antifungal activity at least three times greater than itraconazole and were superior compared to terbinafine in M. canis infected guinea pigs. In a mouse model infected by T. mentagrophytes, again 4c, but not 1c, showed 5-fold superior activity over itraconazole and terbinafine. Compound 2c was effective in both models but less effective than itraconazole in these models. On the basis of these promising results, 4c is currently being clinically investigated for its potential as a novel antifungal agent against dermatophytosis.     

伊曲康唑影响的药代动力学相互作用研究进展

伊曲康唑为三唑类广谱抗真菌药,临床应用广泛,具有CYP3A4和P-糖蛋白抑制作用。由于临床CYP3A4和P-糖蛋白底物广泛,它们在口服药物吸收的主要部位胃肠道均有高表达,同时两者的底物具有显著的重叠性,由此导致的受伊曲康唑影响的药代动力学相互作用广泛产生,甚至引起显著的临床意义。本文综述并讨论了受其影响的药代动力学相互作用研究,以促进临床的安全用药。     

Cost effectiveness of continuous terbinafine compared with intermittent itraconazole in the treatment of dermatophyte toenail onychomycosis: an analysis of based on results from the L.I.ON. study. Lamisil versus Itraconazole in Onychomycosis

OBJECTIVE: To compare the costs and effectiveness of 2 oral antifungal treatment regimens in patients with dermatophyte toenail onychomycosis. DESIGN AND METHODS: A cost-effectiveness analysis using a model based on data from the Lamisil versus Itraconazole in Onychomycosis (L.I.ON.) study, a randomised controlled trial comparing continuous terbinafine with intermittent itraconazole. The trial included 4 treatment arms: terbinafine 250 mg/day for 12 or 16 weeks (T12, T16) and itraconazole 400 mg/day for 1 week in every 4 weeks for 12 or 16 weeks (I3, I4). Cost calculations for 6 countries (Finland, Germany, Iceland, Italy, The Netherlands, UK) included costs for medication, physician visits, laboratory tests, management of adverse events and management of relapse. Effectiveness was based on complete cure rates (mycological cure plus 100% toenail clearing). Costs per complete cure were determined and both average and incremental cost-effectiveness ratios were calculated. PERSPECTIVE: Healthcare system. MAIN OUTCOME MEASURES AND RESULTS: In the L.I.ON. study, terbinafine was seen to be more effective than itraconazole (cure rates, 45.8 vs 23.4%). In most comparisons (5 of the 6 countries), the costs of T12 were statistically significantly lower than those of I3 [range: -37 to -173 euros (EUR); 1998 values; 1.172 US dollars = EUR1], indicating that T12 was the dominant strategy (i.e. less expensive and more effective). One exception (Finland) showed an incremental cost-effectiveness ratio of EUR524 per additional cure. In the other 5 countries, T16 and 14 were essentially equal in cost, but the greater effectiveness of T16 (cure rates, 55.1 vs 25.9%) resulted in a situation of extended dominance. CONCLUSION: From a healthcare system perspective, continuous terbinafine is less costly and more effective than intermittent itraconazole in the treatment of dermatophyte toenail onychomycosis.     

抗真菌药伊曲康唑的药代动力学研究概况

伊曲康唑为三唑类广谱抗真菌药,对浅表真菌、深部真菌感染均有显著疗效,且耐受性良好,临床应用广泛。本文对伊曲康唑在体内的吸收、分布、代谢、排泄的药代动力学特征和影响研究,以及不同患者群体中的药动学作一综述,促进临床合理使用。     

Antimycotic azoles. 7. Synthesis and antifungal properties of a series of novel triazol-3-ones

A series of novel triazol-3-ones have been synthesized, and their in vitro and in vivo antifungal properties are reported. Compound 68 (itraconazole), which displays a pronounced oral activity against vaginal candidosis in rats and against microsporosis in guinea pigs, has been selected for clinical evaluation.     

伊曲康唑治疗口腔念珠菌病安全性与有效性的系统评价#br#

摘要：目的 系统评价伊曲康唑与其他抗真菌药(克霉唑、氟康唑、酮康唑及特比萘芬)相比治疗口腔念珠菌病的临床疗效与安全性,以期为临床提供循证参考。方法 计算机检索PubMed、EMbase、Medline、the Cochrane Library、中国生物医学文献数据库、中国知网、维普数据库和万方数据库。检索时间均从建库到2017年6月。搜集伊曲康唑治疗口腔念珠菌病的随机对照试验(randomized controlled trials, RCTs),采用RevMan 5.3统计软件进行Meta分析。结果 共纳入8项RCT,共计892例患者。Meta分析结果显示：(1)临床治愈率：伊曲康唑组与氟康唑组[RR=0.82, 95%CI(0.62, 1.10), P=0.19]、克霉唑组[RR=1.05, 95%CI(0.87, 1.26), P=0.63]相比临床治愈率差异均无统计学意义;但伊曲康唑组临床治愈率(65.9%)显著高于特比萘芬组(33.3%)。(2)真菌学治愈率：伊曲康唑组与氟康唑组相比,真菌学治愈率差异无统计学意义[RR=0.87, 95%CI(0.75, 1.01), P=0.07]。(3)复发率：伊曲康唑组与氟康唑组相比,复发率差异无统计学意义[RR=0.85, 95%CI(0.51, 1.40), P=0.52]。(4)不良反应发生率：伊曲康唑并不会增加主要胃肠道不良反应[RR=1.10, 95%CI(0.59, 2.05), P=0.77],其他不良反应发生率差异亦无统计学意义。结论 伊曲康唑治疗口腔念珠菌病的有效性和安全性与其他抗真菌药物无显著差异。然而,由于纳入文献质量偏低,提供的信息有限,尚需大规模和高质量的RCT进一步验证。     

Itraconazole. A review of its pharmacodynamic and pharmacokinetic properties, and therapeutic use in superficial and systemic mycoses

Itraconazole is an orally active triazole antifungal drug which has demonstrated a broad spectrum of activity and a favourable pharmacokinetic profile. It is a potent inhibitor of most human fungal pathogens including Aspergillus sp. In non-comparative clinical trials itraconazole was shown to be extremely effective in a wide range of superficial and more serious 'deep' fungal infections when administered once or twice daily. Generally, greater than 80% of patients with superficial dermatophyte or yeast infections are cured by itraconazole. Similarly, good to excellent response rates (clinical cure or marked improvement) are achieved in paracoccidioidomycosis, histoplasmosis, sporotrichosis, blastomycosis, systemic candidiasis, coccidioidomycosis, chromomycosis, aspergillosis and cryptococcosis. Understandably, given the rare nature of some of these diseases, clinical experience is relatively limited and further evaluation, preferably controlled trials with amphotericin B and ketoconazole, would help clarify the ultimate role itraconazole will have in their management. Preliminary findings also indicate that itraconazole may hold promise for the prophylaxis of opportunistic fungal infections in patients at risk, for example women with chronic recurrent vaginal candidiasis, immunodeficient patients with chronic mucocutaneous candidiasis, AIDS patients and patients receiving immunosuppressant drugs. In studies to date itraconazole has been very well tolerated. Transient changes in indices of liver function occurred in 1 to 2% of patients; however, symptomatic liver dysfunction (as occurs infrequently with ketoconazole) has not been reported. Wider clinical experience is needed to permit clear conclusions as to whether liver dysfunction can result from itraconazole administration. Thus, while several aspects of the drug's profile require further investigation, itraconazole is a promising new oral treatment of fungal disease. The extent to which itraconazole will be employed in preference to ketoconazole will be clarified by wider clinical experience.