Fluconazole is a first-generation
triazole antifungal medication. It differs from earlier
azole antifungals (such as
ketoconazole) in that its structure contains a triazole ring instead of an
imidazole ring. While the imidazole antifungals are mainly used topically, fluconazole and certain other triazole antifungals are preferred when systemic treatment is required because of their improved safety and predictable absorption when administered orally. Fluconazole's spectrum of activity includes most species causing
Candidiasis (but not
Pichia kudriavzevii or
Nakaseomyces glabratus, formerly known as
Candida krusei and
C. glabrata),
Cryptococcus neoformans, some dimorphic fungi, and
dermatophytes, among others. Common uses include: • The treatment of non-systemic
Candida infections of the vagina ("yeast infections"), throat, and mouth. • Certain systemic
Candida infections in people with healthy immune systems, including infections of the bloodstream, kidney, or joints. Other antifungals are usually preferred when the infection is in the heart or central nervous system, and for the treatment of active infections in people with weak immune systems. • The prevention of
Candida infections in people with weak immune systems, such as those neutropenic due to cancer chemotherapy, those with advanced HIV infections, transplant patients, and premature infants. • As a second-line agent for the treatment of cryptococcal meningoencephalitis, a fungal infection of the central nervous system.
Resistance Antifungal resistance to drugs in the
azole class tends to occur gradually over the course of prolonged drug therapy, resulting in clinical failure in immunocompromised patients (e.g., patients with advanced
HIV receiving treatment for
thrush or esophageal
Candida infection). In
C. albicans, resistance occurs by way of mutations in the
ERG11 gene, which codes for
14α-demethylase. These mutations prevent the azole drug from binding, while still allowing binding of the enzyme's natural substrate,
lanosterol. Development of resistance to one azole in this way will confer resistance to all drugs in the class. Another resistance mechanism employed by both
C. albicans and
C. glabrata is increasing the rate of efflux of the azole drug from the cell, by both
ATP-binding cassette and major facilitator superfamily transporters. Other gene mutations are also known to contribute to development of resistance. According to the US
Centers for Disease Control and Prevention, fluconazole resistance among
Candida strains in the US is about 7%.
Combating resistance Rising resistance raises concerns since fluconazole is commonly used due to its inexpensiveness and ease of administration, according to the World Health Organization. One possible solution to counter the increasing prevalence of
Candida infections is combination antifungal therapy, combining natural components with commercial antifungal drugs to combat resistance. Another possible solution is the integration of phage therapy, which has shown successive results in functional therapies. Phages, viruses that infect microbes including fungi, exhibit potent antimicrobial effects against various resistant fungal strains, demonstrating remarkable specificity and efficacy. ==Contraindications==