EDP Sciences logo
Web of Conferences logo
Search
Menu
All issues Volume 233 (2026) BIO Web Conf., 233 (2026) 02017 References
Open Access
Issue
BIO Web Conf.
Volume 233, 2026
9th International Conference on Advances in Biosciences and Biotechnology: Emerging Innovations in Biomedical and Bioengineering Sciences (ICABB 2026)
Article Number 02017
Number of page(s) 49
Section Environmental Biotechnology and Sustainable Agriculture
DOI https://doi.org/10.1051/bioconf/202623302017
Published online 23 April 2026
  • Chaudhary, R. Tripathy, A, et al., “Isolation and identification of bioactive compounds from Irpex lacteus wild fleshy fungi: Journal of Pharmaceutical Sciences and Research 7 (2015):424. [Google Scholar]
  • Chowdhury, M.M. Kubra, K. Ahmed, SR, et al., “Screening of antimicrobial, antioxidant properties and bioactive compounds of some edible mushrooms cultivated in Bangladesh,’’ Annals of clinical microbiology and antimicrobials 8 (2015):8. [Google Scholar]
  • Fan, D.D. Wang, W. Zhong, JJ, et al., “Enhancement of cordycepin production in submerged cultures of Cordyceps militaris by addition of ferrous sulfate,’’ Biochemical Engineering Journal 60 (2012) 60:30–5. [Google Scholar]
  • Rousta, N. Aslan, M. Yesilcimen, Akbas, M. Ozcan, F. Sar, T. Taherzadeh, MJ., “Effects of fungal based bioactive compounds on human health,’’ Critical Reviews in Food Science and Nutrition 20 (2024):7004–27. [Google Scholar]
  • Berger, R.G. Bordewick, S. Krahe, N.K. Ersoy. F, et al., “Mycelium vs. fruiting bodies of edible fungi—A comparison of metabolites,’’ Microorganisms 7(2022):13–79. [Google Scholar]
  • Guo, J. Huang, X. Dou, L. Yan, M. Shen, T. Tang, W. Li. J, et al., “Aging and aging-related diseases: from molecular mechanisms to interventions and treatments,’’ Signal transduction and targeted therapy,’’ 7(2022):391. [Google Scholar]
  • Badalyan, S.M. Zambonelli, A, e al., “Biotechnological exploitation of macrofungi for the production of food, pharmaceuticals and cosmeceuticals,’’ In Advances in Macrofungi 30 (2019):199–229. [Google Scholar]
  • Rathore, H. Prasad, S. Kapri, M. Tiwari, A. Sharma, S, et al., “Medicinal importance of mushroom mycelium: Mechanisms and applications,’’ Journal of functional foods 56 (2019): 182–93. [Google Scholar]
  • Yadav, P. Rai, S.N. Mishra, V. Singh, M.P, et al., “Mycoremediation of environmental pollutants: a review with special emphasis on mushrooms,” Environmental Sustainability 4 (2021) :605–18. [Google Scholar]
  • Raj, A. Gauba, P. Bhatt, E, et al., “Advanced nanoparticles for environmental remediation of emerging pollutants: a review,’’ Soil and Sediment Contamination: An International Journal 6 (25):1344–73. [Google Scholar]
  • Nayak, M.A. Tripathi, A. Raj, A. Gauba, P. Bhatt, E., “Chitosan: A Novel Approach and Sustainable Way to Remove Contaminants and Treat Wastewater,” Starch-Starke 4 (2025) 202400171. [Google Scholar]
  • Omoregie, I.P. Oyewole, O.A. Ihotu, K.E. David, A.O, et al., “Chimbekujwo KI, Ameh SS, Oyegbade SA, Adetunji CO. Application of Mushrooms in the Bioremediation of Environmental Pollutants,’’ Mushroom Biotechnology for Improved Agriculture and Human Health 23 (2025):1–28. [Google Scholar]
  • Chandra, P. Enespa, et al., “Fungal enzymes for bioremediation of contaminated soil. InRecent Advancement in White Biotechnology Through Fungi, Perspective for Sustainable Environments 2 (2019): 189–215. [Google Scholar]
  • Agu, K.C. Chidozie, C.P, et al., “An improved slide culture technique for the microscopic identification of fungal species, International Journal of Trend in Scientific Research and Development 6 (2021): 243–54. [Google Scholar]
  • Abril, A.G. Pazos, M. Villa, T.G. Calo-Mata, P. Barros-Velazquez, J. Carrera, M, et al., “Proteomics characterization of food-derived bioactive peptides with anti-allergic and antiinflammatory properties, Nutrients 20 (2022) :4400. [Google Scholar]
  • D^binska, A. Sozanska, B, et al., “Dietary polyphenols—Natural bioactive compounds with potential for preventing and treating some allergic conditions, Nutrients 22 (2023):4823. [Google Scholar]
  • Berger RG, Bordewick S, Krahe NK, Ersoy F. Mycelium vs. fruiting bodies of edible fungi—A comparison of metabolites. Microorganisms. 2022 Jul 8;10(7):1379. [Google Scholar]
  • Lysakowska P, Sobota A, Wirkijowska A. Medicinal mushrooms: Their bioactive components, nutritional value and application in functional food production—A review. Molecules. 2023 Jan;28(14):5393. [Google Scholar]
  • Shin HJ, Ro HS, Kawauchi M, Honda Y. Review on mushroom mycelium-based products and their production process: from upstream to downstream. Bioresources and Bioprocessing. 2025 Jan 10;12(1):3. [Google Scholar]
  • Hamad, D. El-Sayed, H. Ahmed, W. Sonbol, H. Ramadan, M.A, et al., “GC-MS analysis of potentially volatile compounds of Pleurotus ostreatus polar extract: in vitro antimicrobial, cytotoxic, immunomodulatory, and antioxidant activities, Frontiers in Microbiology 13 (2022):834525. [Google Scholar]
  • Oni, J.O. Akomaye, F.A. Markson, A.A. Egwu, A.C, et al., “GC-MS analysis of bioactive compounds in some wild-edible mushrooms from Calabar, Southern Nigeria. European Journal of Biology and Biotechnology, 6 (2020):24–56. [Google Scholar]
  • Manan, S. Atta, O.M. Shahzad, A. Ul-Islam, M. Ullah, M.W. Yang, G, et al., “Applications of fungal mycelium-based functional biomaterials, “In Fungal Biopolymers and Biocomposites Prospects and Avenues 26 (2022) 147–168. [Google Scholar]
  • I. C. Senanayake, A. R. Rathnayaka, D. S. Marasinghe, M. S. Calabon, E. Gentekaki, H. B. Lee, V. G. Hurdeal, D. Pem, L. S. Dissanayake, S. N. Wijesinghe, and D. Bundhun,“Morphological Approaches in Studying Fungi: Collection, Examination, Isolation, Sporulation and Preservation,” Mycosphere 11 (2020): 2678–2754. [Google Scholar]
  • T.Acharya,J.Hare, “Sabouraud Agar and Other Fungal Growth Media,” in Laboratory Protocols in Fungal Biology: Current Methods in Fungal Biology (Cham: Springer International Publishing, 2022), 69–86. [Google Scholar]
  • P. Thakur, S. Khanal, A. Tapwal, D. Kumar, R. Verma, P. Chauhan, and N. Sharma, “Exploring Ganoderma lucidum: Morphology, Cultivation and Market Potential,” World Journal of Microbiology and Biotechnology 40 (2024): 369. [Google Scholar]
  • N. A. Baeshen, Y. Q. Almulaiky, M. Afifi, A. Al-Farga, H. A. Ali, N. N. Baeshen, M. M. Abomughaid, A. M. Abdelazim, and M. N. Baeshen, “GC-MS Analysis of Bioactive Compounds Extracted from Plant Rhazya stricta Using Various Solvents,” Plants 12 (2023): 960. [Google Scholar]
  • P.O.Etinosa,”Mechanical and Interfacial Properties of Biological Materials: From Mycelium Composites to Cell/Surface Interactions on Titanium Surfaces and Bioengineered Bone Structures [Google Scholar]
  • A.Rathi,N.Wadhwa,“Recovery of Mycelial Biomass of Agaricus bisporus, Pleurotus ostreatus, Ganoderma lucidum, Hericium erinaceus: A Comparative Study,” Research and Reviews: A Journal of Microbiology and Virology 14 (2024): 12–18. [Google Scholar]
  • V. Kibona, A. Lupala, E. Mwega, H. Nonga, E. Njau, and R. Mdegela, “Antibacterial and Antifungal Activities of Crude Ethanolic Extracts of Wild Edible Mushrooms Found in Morogoro Municipality, Tanzania,” East African Journal of Science, Technology and Innovation 6 (2025). [Google Scholar]
  • M. Mohany, F. U. Rahman, A. Ahmed, S. S. Al-Rejaie, R. Malik, M. Ahmad, S. Munir, J. Zhang,“Industrial Applications of Fungi,” in Fungal Omics (CRC Press), 192–220. [Google Scholar]
  • S.Munir,H.B.Bozdar,R.A.Memon,“GC-MS, Molecular Identification, Proximate and Mineral Content Composition of Two Wild Mushrooms (Ganoderma lucidum, Pleurotus ostreatus) from Gilgit Baltistan Northern Area of Pakistan,” South African Journal of Botany 163 (2023): 57–64. [Google Scholar]
  • S. K. Niazi, D. S. Basavarajappa, S. H. Kumaraswamy, A. Bepari, H. Hiremath, S. K. Nagaraja, M. Rudrappa, A. Hugar, M. A. Cordero, and S. Nayaka, “GC-MS Based Characterization, Antibacterial, Antifungal and Anti-Oncogenic Activity of Ethyl Acetate Extract of Aspergillus niger Strain AK-6 Isolated from Rhizospheric Soil,” Current Issues in Molecular Biology 45 (2023): 3733–3756. [Google Scholar]
  • D.D.Matyushin,A.K.Buryak,“Application of Regression Learning for Gas Chromatographic Analysis and Prediction of Toxicity of Organic Molecules,” Russian Chemical Bulletin 72 (2023): 482–492.. [Google Scholar]
  • Duke, J.A., Dr. Duke's phytochemical and ethnobotanical databases. 1994. [Google Scholar]
  • D. Chen, Y. Cheng, L. Shi, X. Gao, Y. Huang, and Z. Du, “Design, Synthesis, and Antimicrobial Activity of Amide Derivatives Containing Cyclopropane,” Molecules 29 (2024): 4124. [Google Scholar]
  • O. Matthew, A. James, I. Akogwu, T. Fabunmi, O. Idoko, B. Ebun, Z. Mohammed, and O. Dorathy,“Evaluation of In Vitro Antioxidant, Phytochemical and GC-MS Analysis of Aqueous Extract of Solanum dasyphyllum Fruits,” Journal of Medical and Biological Science Research 7 (2021): 10–14. [Google Scholar]
  • M. I. Agba, B. A. Ngele, P. O. Willie, and F. A. Akomaye, “Effect of Drying Methods on the Phytochemical Composition and Bioactive Compounds of Two Oyster Mushroom Species Using GC-MS,” Tropical Journal of Phytochemistry and Pharmaceutical Sciences 4 (2025): 286–293. [Google Scholar]
  • Duke, James A. (2016). Dr. Duke's Phytochemical and Ethnobotanical Databases. Ag Data Commons. Dataset. https://doi.org/10.15482/USDA.ADC/1239279 [Google Scholar]
  • D. Chen, Y. Cheng, L. Shi, X. Gao, Y. Huang, and Z. Du, “Design, Synthesis, and Antimicrobial Activity of Amide Derivatives Containing Cyclopropane,” Molecules 29 (2024): 4124. [Google Scholar]
  • O. Matthew, A. James, I. Akogwu, T. Fabunmi, O. Idoko, B. Ebun, Z. Mohammed, and O. Dorathy,“Evaluation of In Vitro Antioxidant, Phytochemical and GC-MS Analysis of Aqueous Extract of Solanum dasyphyllum Fruits,” Journal of Medical and Biological Science Research 7 (2021): 10–14. [Google Scholar]
  • Y. Jiao, S. Wang, L. Jiang, X. Sun, J. Li, X. Liu, X. Yao, C. Zhang, N. Wang, H. Deng, and G.Yang,“2-Undecanone Protects Against Fine Particles-Induced Heart Inflammation via Modulating Nrf2/HO-1 and NF-kB Pathways,” Environmental Toxicology 37 (2022): 1642–1652. [Google Scholar]
  • Aditya, Neeraj, J. N. Bhatia, R. S. Jarial, and K. Jarial, “Cultivation Technology Optimization and Identification of Secondary Metabolites from Elm Oyster Mushroom Hypsizygus ulmarius (Bull.) Redhead (Agaricomycetes) Through GC-MS Metabolomic Profiling from India,” Mycologia 117 (2025): 347–373. [Google Scholar]
  • S.Venn-Watson and N. J. Schork, “Pentadecanoic Acid (C15:0), an Essential Fatty Acid, Shares Clinically Relevant Cell-Based Activities with Leading Longevity-Enhancing Compounds,” Nutrients 15 (2023): 4607. [Google Scholar]
  • V. Panwar, B. Dey, J. N. Sheikh, and T. Dutta, “Thermostable Bacterial Laccase for Sustainable Dyeing Using Plant Phenols,” RSC Advances 12 (2022): 18168–18180. [Google Scholar]
  • M. F. Ferdosi, A. Javaid, and I. H. Khan, “Phytochemical Profile of n-Hexane Flower Extract of Cassia fistula L.,” Bangladesh Journal of Botany 51 (2022): 393–399. [Google Scholar]
  • N. N. Uchegbu, T. O. Fasuan, and N. L. Onuoha, “Quantification of Phytochemicals and Compounds’ Identification in Functional Tea from Ficus capensis and Justicia secunda,” Journal of Food Science 88 (2023): 1004–1018. [Google Scholar]
  • T. Babu, M. Mathew, A. Mathew, and R. Kurien, “Antibacterial Activity and GC-MS Analysis of Notothylas indica Kashyap,” Materials Today: Proceedings (2023). [Google Scholar]
  • I. B. Momodu, E. S. Okungbowa, B. O. Agoreyo, and M. M. Maliki, “Gas Chromatography-Mass Spectrometry Identification of Bioactive Compounds in Methanol and Aqueous Seed Extracts of Azanza garckeana Fruits,” Nigerian Journal of Biotechnology 38 (2022): 25–38. [Google Scholar]
  • S. Nisa, Y. Bibi, S. Masood, A. Ali, S. Alam, M. Sabir, A. Qayyum, W. Ahmed, S. Alharthi, E.Y.Santali,SA.Alharthy, “Isolation, Characterization and Anticancer Activity of Two Bioactive Compounds from Arisaema flavum (Forssk.) Schott,” Molecules 27 (2022): 7932. [Google Scholar]
  • B. Govindaswamy, B. Ravikrishnan, D. Panda, and S. Perumal, “In Vitro Anticancer, AntiInflammatory and Antioxidant Activity of Celery Oil (Apium graveolens)-Myristic Acid Based Microemulsion System: Characterization and Biomedical Application,” bioRxiv (2024). [Google Scholar]
  • K. Agrawal, M. Gokhale, and R. Faraz, “Insecticidal and Antimicrobial Activity of Ethanolic Extract of Lantana camara and GC-MS Analysis,” International Journal of Plant and Environment 10 (2024): 69–78. [Google Scholar]
  • S. Venn-Watson and N. J. Schork, “Pentadecanoic Acid (C15:0), an Essential Fatty Acid, Shares Clinically Relevant Cell-Based Activities with Leading Longevity-Enhancing Compounds,” Nutrients 15 (2023): 4607. [Google Scholar]
  • V. Panwar, B. Dey, J. N. Sheikh, and T. Dutta, “Thermostable Bacterial Laccase for Sustainable Dyeing Using Plant Phenols,” RSC Advances 12 (2022): 18168–18180. [Google Scholar]
  • M. F. Ferdosi, A. Javaid, and I. H. Khan, “Phytochemical Profile of n-Hexane Flower Extract of Cassia fistula L.,” Bangladesh Journal of Botany 51 (2022): 393–399. [Google Scholar]
  • N. N. Uchegbu, T. O. Fasuan, and N. L. Onuoha, “Quantification of Phytochemicals and Compounds’ Identification in Functional Tea from Ficus capensis and Justicia secunda,” Journal of Food Science 88 (2023): 1004–1018. [Google Scholar]
  • T. Babu, M. Mathew, A. Mathew, and R. Kurien, “Antibacterial Activity and GC-MS Analysis of Notothylas indica Kashyap,” Materials Today: Proceedings (2023). [Google Scholar]
  • I. B. Momodu, E. S. Okungbowa, B. O. Agoreyo, and M. M. Maliki, “Gas Chromatography-Mass Spectrometry Identification of Bioactive Compounds in Methanol and Aqueous Seed Extracts of Azanza garckeana Fruits,” Nigerian Journal of Biotechnology 38 (2022): 25–38. [Google Scholar]
  • S. Nisa, Y. Bibi, S. Masood, A. Ali, S. Alam, M. Sabir, A. Qayyum, W. Ahmed, S. Alharthi, E. Y. Santali, and S. A. Alharthy, “Isolation, Characterization and Anticancer Activity of Two Bioactive Compounds from Arisaema flavum (Forssk.) Schott,” Molecules 27 (2022): 7932. [Google Scholar]
  • B. Govindaswamy, B. Ravikrishnan, D. Panda, and S. Perumal, “In Vitro Anticancer, AntiInflammatory and Antioxidant Activity of Celery Oil (Apium graveolens)-Myristic Acid Based Microemulsion System: Characterization and Biomedical Application,” bioRxiv (2024). [Google Scholar]
  • K. Agrawal, M. Gokhale, and R. Faraz, “Insecticidal and Antimicrobial Activity of Ethanolic Extract of Lantana camara and GC-MS Analysis,” International Journal of Plant and Environment 10 (2024): 69–78. [Google Scholar]
  • V. Panwar, B. Dey, J. N. Sheikh, and T. Dutta, “Thermostable Bacterial Laccase for Sustainable Dyeing Using Plant Phenols,” RSC Advances 12 (2022): 18168–18180. [Google Scholar]
  • M. F. Ferdosi, A. Javaid, and I. H. Khan, “Phytochemical Profile of n-Hexane Flower Extract of Cassia fistula L.,” Bangladesh Journal of Botany 51 (2022): 393–399. [Google Scholar]
  • N. N. Uchegbu, T. O. Fasuan, and N. L. Onuoha, “Quantification of Phytochemicals and Compounds’ Identification in Functional Tea from Ficus capensis and Justicia secunda,” Journal of Food Science 88 (2023): 1004–1018. [Google Scholar]
  • T. Babu, M. Mathew, A. Mathew, and R. Kurien, “Antibacterial Activity and GC-MS Analysis of Notothylas indica Kashyap,” Materials Today: Proceedings (2023). [Google Scholar]
  • I. B. Momodu, E. S. Okungbowa, B. O. Agoreyo, and M. M. Maliki, “Gas Chromatography-Mass Spectrometry Identification of Bioactive Compounds in Methanol and Aqueous Seed Extracts of Azanza garckeana Fruits,” Nigerian Journal of Biotechnology 38 (2022): 25–38. [Google Scholar]
  • S. Nisa et al., “Isolation, Characterization and Anticancer Activity of Two Bioactive Compounds from Arisaema flavum (Forssk.) Schott,” Molecules 27 (2022): 7932. [Google Scholar]
  • B. Govindaswamy et al., “In Vitro Anticancer, Anti-Inflammatory and Antioxidant Activity of Celery Oil (Apium graveolens)-Myristic Acid Based Microemulsion System: Characterization and Biomedical Application,” bioRxiv (2024). [Google Scholar]
  • K. Agrawal, M. Gokhale, and R. Faraz, “Insecticidal and Antimicrobial Activity of Ethanolic Extract of Lantana camara and GC-MS Analysis,” International Journal of Plant and Environment 10 (2024): 69–78. [Google Scholar]
  • A. A. Salaudeen, S. M. Dangoggo, U. Z. Faruq, and H. E. Mshelia, “Phytochemical and Antibacterial Activity of Stem Bark Extract of Cordia africana Lam.” 8 (2022): 7–23. [Google Scholar]
  • R. Charlet, C. Le Danvic, B. Sendid, P. Nagnan-Le Meillour, and S. Jawhara, “Oleic Acid and Palmitic Acid from Bacteroides thetaiotaomicron and Lactobacillus johnsonii Exhibit Anti-Inflammatory and Antifungal Properties,” Microorganisms 10 (2022): 1803. [Google Scholar]
  • S. K. Al-Taie, N. F. M. Al-Kenane, and Z. T. Al-Aqbi, “GC-MS Analysis of Bioactive Constituents from the Leaves of Portulaca afra Jacq. and Portulaca grandiflora Hook.,” Al-Mustaqbal Journal of Pharmaceutical and Medical Sciences 3 (2025): 4–24. [Google Scholar]
  • S. A. Alsalamah et al., “Ultraviolet Radiation Effect on Chemical Profile of Sage Oil and Its Inhibitor Capacity for Butyrylcholinesterase, a-Amylase, Protein Denaturation, Cancer and Pathogenic Yeasts,” BioResources 20 (2025):8–23. [Google Scholar]
  • C. Xie, S. Wang, M. Cao, W. Xiong, and L. Wu, “(E)-9-Octadecenoic Acid Ethyl Ester Derived from Lotus Seedpod Ameliorates Inflammatory Responses by Regulating MAPKs and NF-kB Signalling Pathways in LPS-Induced RAW264.7 Macrophages,” EvidenceBased Complementary and Alternative Medicine (2022): 6731360. [Google Scholar]
  • Z. Li et al., “Investigating the Therapeutic Potential of Ganoderma lucidum in Treating Optic Nerve Atrophy through Network Pharmacology and Experimental Validation,” Biochemical and Biophysical Research Communications 760 (2025): 151702. [Google Scholar]
  • R. M. Rukmana et al., “Phytochemical Profile, Antioxidant Activity and Anticancer Activity of Gamma-Irradiated Black Rice Bran (Oryza sativa L.) Ethanolic Extract: InVitro and In-Silico Study,” Science and Technology Indonesia 10 (2025): 628–643. [Google Scholar]
  • A. T. Brinca et al., “The Potential of Volatilomics as Female Fertilization Biomarkers in Assisted Reproductive Techniques,” Biomedicines 14 (2026): 264. [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.