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Huan Yang, Li He, Shuang Pan, Hui Liu, Xiaoli Hu (2019)
Nitrogen-doped fluorescent carbon dots for highly sensitive and selective detection of tannic acid.Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy, 210
S. Chopra, Dharmender Kumar (2020)
Ibuprofen as an emerging organic contaminant in environment, distribution and remediationHeliyon, 6
H. Shagholani, S. Ghoreishi (2017)
Investigation of tannic acid cross-linked onto magnetite nanoparticles for applying in drug delivery systemsJournal of Drug Delivery Science and Technology, 39
N. Sahiner, Selin Sagbas, Mehtap Sahiner, C. Si̇lan (2017)
P(TA) macro-, micro-, nanoparticle-embedded super porous p(HEMA) cryogels as wound dressing material.Materials science & engineering. C, Materials for biological applications, 70 Pt 1
Yueqing Wang, Si Chen, Shuya Zhao, Qianwu Chen, Jintao Zhang (2020)
Interfacial coordination assembly of tannic acid with metal ions on three-dimensional nickel hydroxide nanowalls for efficient water splittingJournal of Materials Chemistry A
Xiao Yang, Pei Huang, Haihuan Wang, Shuang Cai, Yixue Liao, Ziqin Mo, Xinyuan Xu, Chunmei Ding, Changsheng Zhao, Jianshu Li (2017)
Antibacterial and anti-biofouling coating on hydroxyapatite surface based on peptide-modified tannic acid.Colloids and surfaces. B, Biointerfaces, 160
B. Kaczmarek (2020)
Tannic Acid with Antiviral and Antibacterial Activity as A Promising Component of Biomaterials—A MinireviewMaterials, 13
Milad Khansary, G. Walker, S. Shirazian (2020)
Incomplete cocrystalization of ibuprofen and nicotinamide and its interplay with formation of ibuprofen dimer and/or nicotinamide dimer: A thermodynamic analysis based on DFT data.International journal of pharmaceutics
Chao Wu, T. Li, Chenbo Liao, Lei Li, Jun Yang (2017)
Tea polyphenol-inspired tannic acid-treated polypropylene membrane as a stable separator for lithium–oxygen batteriesJournal of Materials Chemistry, 5
S. Moradi, F. Khodaiyan, Seyed Razavi (2019)
Green construction of recyclable amino-tannic acid modified magnetic nanoparticles: application for β-glucosidase immobilization.International journal of biological macromolecules
C. Bavatharani, E. Muthusankar, S. Wabaidur, Z. Alothman, K. Alsheetan, M. Al-Anazy, D. Ragupathy (2020)
Electrospinning technique for production of polyaniline nanocomposites/nanofibres for multi-functional applications: A reviewSynthetic Metals
Digital camera images of TA and TA-based fibers against S. aureus (gram +) and E. coli (gram -) bacteria (gentamicin was used as a control)
B Kaczmarek (2020)
249Fiber. Polym., 9
Jianping Zhang, Qiongtao Song, Xue Han, Yuan-yuan Zhang, Ying Zhang, Xuan Zhang, Xi Chu, Fenghua Zhang, L. Chu (2017)
Multi‐targeted protection of acetaminophen‐induced hepatotoxicity in mice by tannic acidInternational Immunopharmacology, 47
N. Aelenei, Marcel Popa, O. Novac, G. Lisa, Lacramioara Balaita (2009)
Tannic acid incorporation in chitosan-based microparticles and in vitro controlled releaseJournal of Materials Science: Materials in Medicine, 20
Wen Zhang, Zhi-Yi Yang, R. Tang, Jinping Guan, Yi-Fan Qiao (2020)
Application of tannic acid and ferrous ion complex as eco-friendly flame retardant and antibacterial agents for silkJournal of Cleaner Production, 250
J. Beltrán-Heredia, J. Sánchez-Martín, C. Martín-Sánchez (2011)
Remediation of Dye-Polluted Solutions by a New Tannin-Based CoagulantIndustrial & Engineering Chemistry Research, 50
Narges Dastmalchi, B. Baradaran, S. Latifi-Navid, R. Safaralizadeh, S. Khojasteh, Mohammad Amini, Elmira Roshani, Parisa Lotfinejad (2020)
Antioxidants with two faces toward cancer.Life sciences
and H
M. Shin, J. Ryu, Joseph Park, Keumyeon Kim, Jaewook Yang, Haeshin Lee (2015)
DNA/Tannic Acid Hybrid Gel Exhibiting Biodegradability, Extensibility, Tissue Adhesiveness, and Hemostatic AbilityAdvanced Functional Materials, 25
Bin Zhou, Xiaoqian Hu, Jinjin Zhu, Zhenzhen Wang, Xichang Wang, Mingfu Wang (2016)
Release properties of tannic acid from hydrogen bond driven antioxidative cellulose nanofibrous films.International journal of biological macromolecules, 91
N. Sahiner, Selin Sagbas, N. Aktas (2015)
Single step natural poly(tannic acid) particle preparation as multitalented biomaterial.Materials science & engineering. C, Materials for biological applications, 49
Ya-Nan Chen, Chen Jiao, Yaxin Zhao, Jianan Zhang, Huiliang Wang (2018)
Self-Assembled Polyvinyl Alcohol–Tannic Acid Hydrogels with Diverse Microstructures and Good Mechanical PropertiesACS Omega, 3
Weiqiao Yang, A. Sousa, A. Thomas-Gahring, Xuetong Fan, T. Jin, Xihong Li, P. Tomasula, Linshu Liu (2016)
Electrospun Polymer Nanofibers Reinforced by Tannic Acid/Fe+++ Complexes †Materials, 9
G. Pasquale, L. Ostedgaard, D. Vermeer, W. Swaim, Philip Karp, J. Chiorini (2011)
Bovine AAV Transcytosis Inhibition by Tannic Acid Results in Functional Expression of CFTR in Vitro and Altered Bio-Distribution in VivoGene therapy, 19
P. Taheri, Reza Jahanmardi, M. Koosha, S. Abdi (2020)
Physical, mechanical and wound healing properties of chitosan/gelatin blend films containing tannic acid and/or bacterial nanocellulose.International journal of biological macromolecules
I. Perelshtein, Elena Ruderman, A. Francesko, M. Fernandes, T. Tzanov, A. Gedanken (2014)
Tannic acid NPs - synthesis and immobilization onto a solid surface in a one-step process and their antibacterial and anti-inflammatory properties.Ultrasonics sonochemistry, 21 6
C. Xie, Huai-fen Li (2010)
Determination of tannic acid in industrial wastewater based on chemiluminescence system of KIO₄-H₂O₂-Tween40.Luminescence : the journal of biological and chemical luminescence, 25 5
M. Allais, Domitille Mailley, P. Hébraud, D. Ihiawakrim, V. Ball, F. Meyer, A. Hébraud, G. Schlatter (2018)
Polymer-free electrospinning of tannic acid and cross-linking in water for hybrid supramolecular nanofibres.Nanoscale, 10 19
Jacob Aranda, Ronald Thomas (2006)
Systematic review: intravenous Ibuprofen in preterm newborns.Seminars in perinatology, 30 3
Fei Liu, V. Kozlovskaya, Oleksandra Zavgorodnya, Claudia Martinez-Lopez, S. Catledge, E. Kharlampieva (2014)
Encapsulation of anticancer drug by hydrogen-bonded multilayers of tannic acid.Soft matter, 10 46
W. Khan, R. Asmatulu, M. Ceylan, A. Jabbarnia (2013)
Recent progress on conventional and non-conventional electrospinning processesFibers and Polymers, 14
L Guangming (2009)
284Fiber. Polym., 28
Lihui Tan, Xiang Zhou, Keke Wu, Deguang Yang, Y. Jiao, Changren Zhou (2020)
Tannic acid/CaII anchored on the surface of chitin nanofiber sponge by layer-by-layer deposition: Integrating effective antibacterial and hemostatic performance.International journal of biological macromolecules
Yuxiang Huang, Qiuqin Lin, Yanglun Yu, Wenji Yu (2020)
Functionalization of wood fibers based on immobilization of tannic acid and in situ complexation of Fe (II) ionsApplied Surface Science, 510
Yaoguang Li, Dongyun Ma, Dexiang Sun, Chenyang Wang, Jian Zhang, Ying-xin Xie, T. Guo (2015)
Total phenolic, flavonoid content, and antioxidant activity of flour, noodles, and steamed bread made from different colored wheat grains by three milling methodsCrop Journal, 3
Shuheng Wu, Yujian Yan, Daniliak Ni, Xianhu Pan, Xin Chen, Jintao Guan, Xuemin Xiong, Liangqi Liu (2019)
Development of a safe and efficient gene delivery system based on a biodegradable tannic acid backbone.Colloids and surfaces. B, Biointerfaces, 183
T. Wahyono, Dewi Astuti, I Wiryawan, I. Sugoro, A. Jayanegara (2019)
Fourier Transform Mid-Infrared (FTIR) Spectroscopy to Identify Tannin Compounds in The Panicle of Sorghum Mutant LinesIOP Conference Series: Materials Science and Engineering, 546
Heriberto Rodríguez‐Tobías, G. Morales, D. Grande (2019)
Comprehensive review on electrospinning techniques as versatile approaches toward antimicrobial biopolymeric composite fibers.Materials science & engineering. C, Materials for biological applications, 101
Michaela Fiol, Annika Weckmüller, S. Neugart, M. Schreiner, S. Rohn, A. Krumbein, L. Kroh (2013)
Thermal-induced changes of kale's antioxidant activity analyzed by HPLC-UV/Vis-online-TEAC detection.Food chemistry, 138 2-3
Jing Huang, Yanxiang Cheng, Yang Wu, Xiaowen Shi, Yumin Du, Hongbing Deng (2019)
Chitosan/tannic acid bilayers layer-by-layer deposited cellulose nanofibrous mats for antibacterial application.International journal of biological macromolecules
C. Drosou, M. Krokida, C. Biliaderis (2017)
Composite pullulan-whey protein nanofibers made by electrospinning: Impact of process parameters on fiber morphology and physical propertiesFood Hydrocolloids, 77
Mostafa Amirinejad, Javid Davoodi, M. Abbaspour, A. Akhgari, F. Hadizadeh, A. Badiee (2020)
Preparation, characterization and improved release profile of ibuprofen-phospholipid associationJournal of Drug Delivery Science and Technology, 60
N. Sahiner, Selin Sagbas, Mehtap Sahiner, Sahin Demirci (2016)
Degradable tannic acid/polyethyleneimine polyplex particles with highly antioxidant and antimicrobial effectsPolymer Degradation and Stability, 133
Tong Li, Yirong Xiao, Dongxue Guo, Liguo Shen, Renjie Li, Y. Jiao, Yanchao Xu, Hongjun Lin (2020)
In-situ coating TiO2 surface by plant-inspired tannic acid for fabrication of thin film nanocomposite nanofiltration membranes toward enhanced separation and antibacterial performance.Journal of colloid and interface science, 572
A. Pizzi (2019)
Tannins: Prospectives and Actual Industrial ApplicationsBiomolecules, 9
Cen Zhang, Feng-qin Feng, Hui Zhang (2018)
Emulsion electrospinning: Fundamentals, food applications and prospectsTrends in Food Science & Technology
M. Cipriano‐Salazar, S. Rojas-Hernández, J. Olivares-Pérez, R. Jiménez-Guillén, B. Cruz-Lagunas, L. Camacho-Diaz, A. Ugbogu (2018)
Antibacterial activities of tannic acid against isolated ruminal bacteria from sheep.Microbial pathogenesis, 117
F. Mohammadi, N. Golafshan, M. Kharaziha, A. Ashrafi (2019)
Chitosan-heparin nanoparticle coating on anodized NiTi for improvement of blood compatibility and biocompatibility.International journal of biological macromolecules, 127
Adrian Bombin, N. Dunne, H. McCarthy (2020)
Electrospinning of natural polymers for the production of nanofibres for wound healing applications.Materials science & engineering. C, Materials for biological applications, 114
Wentao Yan, Mengqi Shi, Chenxi Dong, Lifen Liu, Cong-jie Gao (2020)
Applications of tannic acid in membrane technologies: A review.Advances in colloid and interface science, 284
P. Arapitsas (2012)
Hydrolyzable tannin analysis in food.Food chemistry, 135 3
N. Khan, Aamir Ahmad, S. Hadi (2000)
Anti-oxidant, pro-oxidant properties of tannic acid and its binding to DNA.Chemico-biological interactions, 125 3
J. Jing, Shufeng Liang, Yufei Yan, Xin Tian, Xinming Li (2019)
Fabrication of Hybrid Hydrogels from Silk Fibroin and Tannic Acid with Enhanced Gelation and Antibacterial Activities.ACS biomaterials science & engineering, 5 9
G. Palma, J. Freer, J. Baeza (2003)
Removal of metal ions by modified Pinus radiata bark and tannins from water solutions.Water research, 37 20
Tannic acid (TA) is a plant-based polyphenolic molecule with enticing anti-oxidant, anti-bacterial, anti-inflammatory and anti-cancer features, making it a valuable material in bio-medicinal applications. To establish whether TA-based fibers are useful tools in potential medical textiles, e.g., as wound dressing material for prophylaxis against infections and diseases, TA fibers were prepared and employed in biological assays. TA fibers were prepared with 55 weight% TA in ethanol-DI water mixture and fabricated by the electrospinning technique. Bare TA-based fibers were examined and were 1.2±0.1 % non-hemolytic and had 8.7±1.7 blood clotting index up to 2 mg/ml concentration. Degradation of bare TA-based fibers was completed in 5 minutes; however, degradation of crosslinked TA-based fibers were 98.3±2.3 % and 83.1±5.4 % for TA-Ibu and TA in 168 hours. Anti-oxidant activity of TA-based fibers was investigated by TEAC, total phenol content (TPC) and total flavonoid content (TFC) assays. Bare TA fibers possessed the highest anti-oxidant activity of 5.7±0.5 mM trolox equivalent/g, 168.0±2.0 gallic acid equivalent µg/ml and 193.0±17.0 quercetin equivalent µg/ml. Anti-bacterial activity was investigated by the disc diffusion method and the highest inhibition zone diameter was measured as 3.5±0.2 cm against S. aureus (gram +) bacteria; however, the same fiber was detected as producing 2.2±0.5 cm zone diameter for E. coli (gram -) bacteria.
Fibers and Polymers – Springer Journals
Published: Nov 1, 2021
Keywords: Tannic acid fiber; Electrospinning; Wound dressing; Medical textile; Medical patch
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