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OpenAlex Citation Counts

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OpenAlex is a bibliographic catalogue of scientific papers, authors and institutions accessible in open access mode, named after the Library of Alexandria. It's citation coverage is excellent and I hope you will find utility in this listing of citing articles!

If you click the article title, you'll navigate to the article, as listed in CrossRef. If you click the Open Access links, you'll navigate to the "best Open Access location". Clicking the citation count will open this listing for that article. Lastly at the bottom of the page, you'll find basic pagination options.

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Showing 1-25 of 181 citing articles:

Candidiasis and Mechanisms of Antifungal Resistance
Somanon Bhattacharya, Sutthichai Sae-Tia, Bettina C. Fries
Antibiotics (2020) Vol. 9, Iss. 6, pp. 312-312
Open Access | Times Cited: 384
Regulation of Ergosterol Biosynthesis in Saccharomyces cerevisiae
Tania Jordá, Sergi Puig
Genes (2020) Vol. 11, Iss. 7, pp. 795-795
Open Access | Times Cited: 346
Pathogenesis and virulence of Candida albicans
José Pedro Lopes, Michail S. Lionakis
Virulence (2021) Vol. 13, Iss. 1, pp. 89-121
Open Access | Times Cited: 258
The Multifunctional Fungal Ergosterol
Márcio L. Rodrigues
mBio (2018) Vol. 9, Iss. 5
Open Access | Times Cited: 207
Antifungal Drugs
Jiří Houšť, J. Spížek, Vladimı́r Havlı́ček
Metabolites (2020) Vol. 10, Iss. 3, pp. 106-106
Open Access | Times Cited: 190
Antifungal resistance in dermatophytes: Recent trends and therapeutic implications
Ananta Khurana, Kabir Sardana, Anuradha Chowdhary
Fungal Genetics and Biology (2019) Vol. 132, pp. 103255-103255
Closed Access | Times Cited: 173
Biofilm Formation in Medically Important Candida Species
Zuzana Malinovská, E. Čonková, P. Váczi
Journal of Fungi (2023) Vol. 9, Iss. 10, pp. 955-955
Open Access | Times Cited: 59
Molecular Mechanisms Associated with Antifungal Resistance in Pathogenic Candida Species
Karolina Czajka, Krishnan Venkataraman, Danielle Brabant-Kirwan, et al.
Cells (2023) Vol. 12, Iss. 22, pp. 2655-2655
Open Access | Times Cited: 56
The Significance of Mono‐ and Dual‐Effective Agents in the Development of New Antifungal Strategies
Cengiz Zobi, Öztekin Algül
Chemical Biology & Drug Design (2025) Vol. 105, Iss. 1
Open Access | Times Cited: 2
The negative cofactor 2 complex is a key regulator of drug resistance in Aspergillus fumigatus
Takanori Furukawa, Norman van Rhijn, Marcin G. Fraczek, et al.
Nature Communications (2020) Vol. 11, Iss. 1
Open Access | Times Cited: 124
Combatting the evolution of antifungal resistance in Cryptococcus neoformans
Arianne Bermas, Jennifer Geddes‐McAlister
Molecular Microbiology (2020) Vol. 114, Iss. 5, pp. 721-734
Open Access | Times Cited: 108
Gene Duplication Associated with Increased Fluconazole Tolerance in Candida auris cells of Advanced Generational Age
Somanon Bhattacharya, Thomas Holowka, Erika P. Orner, et al.
Scientific Reports (2019) Vol. 9, Iss. 1
Open Access | Times Cited: 86
Multi-omics Signature of Candida auris , an Emerging and Multidrug-Resistant Pathogen
Daniel Zamith‐Miranda, Heino Heyman, Levi G. Cleare, et al.
mSystems (2019) Vol. 4, Iss. 4
Open Access | Times Cited: 84
Ergosterol distribution controls surface structure formation and fungal pathogenicity
Hau Lam Choy, Elizabeth A. Gaylord, Tamara L. Doering
mBio (2023)
Open Access | Times Cited: 23
Citizen science reveals landscape-scale exposures to multiazole-resistant Aspergillus fumigatus bioaerosols
Jennifer M. G. Shelton, Johanna Rhodes, Christopher B. Uzzell, et al.
Science Advances (2023) Vol. 9, Iss. 29
Open Access | Times Cited: 23
Acquired amphotericin B resistance leads to fitness trade-offs that can be mitigated by compensatory evolution in Candida auris
Hans Carolus, Dimitrios Sofras, Giorgio Boccarella, et al.
Nature Microbiology (2024) Vol. 9, Iss. 12, pp. 3304-3320
Closed Access | Times Cited: 10
The role of gene copy number variation in antimicrobial resistance in human fungal pathogens
Alan R. Jay, David Jordan, Aleeza C. Gerstein, et al.
npj Antimicrobials and Resistance (2025) Vol. 3, Iss. 1
Open Access | Times Cited: 1
An agricultural triazole induces genomic instability and haploid cell formation in the human fungal pathogen Candida tropicalis
Tianren Hu, Qiushi Zheng, Chengjun Cao, et al.
PLoS Biology (2025) Vol. 23, Iss. 4, pp. e3003062-e3003062
Open Access | Times Cited: 1
Experimental Evolution Identifies Adaptive Aneuploidy as a Mechanism of Fluconazole Resistance in Candida auris
Jian Bing, Tianren Hu, Qiushi Zheng, et al.
Antimicrobial Agents and Chemotherapy (2020) Vol. 65, Iss. 1
Open Access | Times Cited: 68
Antifungal effects of statins
Alireza Tavakkoli, Thomas P. Johnston, Amirhossein Sahebkar
Pharmacology & Therapeutics (2020) Vol. 208, pp. 107483-107483
Closed Access | Times Cited: 63
The wide‐ranging phenotypes of ergosterol biosynthesis mutants, and implications for microbial cell factories
Emily J. Johnston, Tessa Moses, Susan J. Rosser
Yeast (2019) Vol. 37, Iss. 1, pp. 27-44
Open Access | Times Cited: 59
Citronellal Exerts Its Antifungal Activity by Targeting Ergosterol Biosynthesis in Penicillium digitatum
Qiuli OuYang, Yangmei Liu, Okwong Oketch Reymick, et al.
Journal of Fungi (2021) Vol. 7, Iss. 6, pp. 432-432
Open Access | Times Cited: 54
Synthetic biology: a new frontier in food production
Shuobo Shi, Zhihui Wang, Lirong Shen, et al.
Trends in biotechnology (2022) Vol. 40, Iss. 7, pp. 781-803
Closed Access | Times Cited: 36
Phytoconstituents and Ergosterol Biosynthesis-Targeting Antimicrobial Activity of Nutmeg (Myristica fragans Houtt.) against Phytopathogens
Adriana Cruz, Eva Sánchez‐Hernández, Ana Teixeira, et al.
Molecules (2024) Vol. 29, Iss. 2, pp. 471-471
Open Access | Times Cited: 8
Verazine Biosynthesis from Simple Sugars in Engineered Saccharomyces cerevisiae
Peter H. Winegar, Graham A. Hudson, Luisa B. Dell, et al.
Metabolic Engineering (2024) Vol. 85, pp. 145-158
Closed Access | Times Cited: 6
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