This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Rabiei N, Kish MH, Amirshahi SH, Radjabian M. The Kinetic and Thermodynamic Parameters of Dyeing of Polypropylene/Clay Composite Fibers Using Disperse Dye. Dyes & Pigments 2012; 94(3): 386–92.RabieiNKishMHAmirshahiSHRadjabianMThe Kinetic and Thermodynamic Parameters of Dyeing of Polypropylene/Clay Composite Fibers Using Disperse Dye20129433869210.1016/j.dyepig.2012.02.010Search in Google Scholar
Zhang CH, Yang Fl, Wang WJ, Chen B. Preparation and Characterization of Hydrophilic Modification of Polypropylene Non-woven Fabric by Dip-coating PVA (Polyvinyl Alcohol). Separation & Purification Technology 2008; 61(3): 276–86.ZhangCHYangFlWangWJChenBPreparation and Characterization of Hydrophilic Modification of Polypropylene Non-woven Fabric by Dip-coating PVA (Polyvinyl Alcohol)20086132768610.1016/j.seppur.2007.10.019Search in Google Scholar
Liu K, Zhou NY, Xie CX, Mou B, Ai YN. Design Dopamine-modified Polypropylene Fibers Towards Removal of Heavy Metal Ions from Water. AIP Advances 2017; 7(4): 1–8. DOI: 10.1063/1.49799 25.LiuKZhouNYXieCXMouBAiYNDesign Dopamine-modified Polypropylene Fibers Towards Removal of Heavy Metal Ions from Water2017741810.1063/1.49799 25Open DOISearch in Google Scholar
Lee KW, Mccarthy TJ. Surface-selective Hydroxylation of Polypropylene. Macromolecules 1988; 21(2): 309–13.LeeKWMccarthyTJSurface-selective Hydroxylation of Polypropylene19882123091310.1021/ma00180a005Search in Google Scholar
Ren X, Liu PZ, Lee ML. Cellulose Modified Polypropylene Hollow Fibers for Capillary Electrophoresis. Journal of Microcolumn Separations 1996; 8(8): 529–534.RenXLiuPZLeeMLCellulose Modified Polypropylene Hollow Fibers for Capillary Electrophoresis19968852953410.1002/(SICI)1520-667X(1996)8:8<529::AID-MCS2>3.0.CO;2-3Search in Google Scholar
Jiang G, Hu R, Wang X, Xi X, Wang R, Wei Z, et al. Preparation of Superhydrophobic and Superoleophilic Polypropylene Fibers with Application in Oil/Water Separation. Journal of the Textile Institute Proceedings & Abstracts 2013; 104(8): 790–7. DOI: 10.1080/00405000.2012.757008.JiangGHuRWangXXiXWangRWeiZPreparation of Superhydrophobic and Superoleophilic Polypropylene Fibers with Application in Oil/Water Separation20131048790710.1080/00405000.2012.757008Open DOISearch in Google Scholar
Carlsson DJ, Clark F, Wiles DM. The Photo-Oxidation of Polypropylene Monofilaments3 Part I: Chemical Changes and Mechanical Deterioration. Textile Research Journal 1976; 46(8): 590–9. DOI: 10.1177/004051757604600806.CarlssonDJClarkFWilesDMThe Photo-Oxidation of Polypropylene Monofilaments3 Part I: Chemical Changes and Mechanical Deterioration1976468590910.1177/004051757604600806Open DOISearch in Google Scholar
Dorey S, Gaston F, Marque S, Bortolotti B, Dupuy N. XPS Analysis of PE and EVA Samples Irradiated at Different γ-doses. Applied Surface Science 2017; 427 (pt.b): 966–72.DoreySGastonFMarqueSBortolottiBDupuyNXPS Analysis of PE and EVA Samples Irradiated at Different γ-doses2017427(pt.b)9667210.1016/j.apsusc.2017.09.001Search in Google Scholar
Payamara J, Shahidi S, Ghoranneviss M, Wiener J, Anvari A. Effect of Electron Irradiation on Dye and Printability of Polypropylene (PP) Fabrics: a Novel Method for Decoration of PP Fabrics. The Journal of The Textile Institute 2010; 101(11): 988–95. DOI: 10.1080/00405000903083278.PayamaraJShahidiSGhorannevissMWienerJAnvariAEffect of Electron Irradiation on Dye and Printability of Polypropylene (PP) Fabrics: a Novel Method for Decoration of PP Fabrics2010101119889510.1080/00405000903083278Open DOISearch in Google Scholar
Kim MS, Khang G, Hai BL. Gradient Polymer Surfaces for Biomedical Applications. Progress in Polymer Science 2008; 33(1): 138–64.KimMSKhangGHaiBLGradient Polymer Surfaces for Biomedical Applications20083311386410.1016/j.progpolymsci.2007.06.001Search in Google Scholar
Shahidi S, Ghoranneviss M. Comparison Between Oxygen and Nitrogen Plasma Treatment on Adhesion Properties and Antibacterial Activity of Metal Coated Polypropylene Fabrics. Fibers and Polymers 2012; 13(8): 971–8. DOI: 10.1007/s12221-012-0971-5.ShahidiSGhorannevissMComparison Between Oxygen and Nitrogen Plasma Treatment on Adhesion Properties and Antibacterial Activity of Metal Coated Polypropylene Fabrics2012138971810.1007/s12221-012-0971-5Open DOISearch in Google Scholar
Zille A, Oliveira FR, Souto AP. Plasma Treatment in Textile Industry. Plasma Processes and Polymers. 2015; 12(2): 98–131.ZilleAOliveiraFRSoutoAPPlasma Treatment in Textile Industry20151229813110.1002/ppap.201400052Search in Google Scholar
Garcia D, Fenollar O, Lopez R, Sanchis R, Balart R. Durability of the Wettability Properties of a Polypropylene Film with a Low-pressure CH4-O2 Plasma Treatment. Journal of Applied Polymerence 2008; 110(2): 1201–7.GarciaDFenollarOLopezRSanchisRBalartRDurability of the Wettability Properties of a Polypropylene Film with a Low-pressure CH4-O2 Plasma Treatment200811021201710.1002/app.28563Search in Google Scholar
Sciarratta V, Vohrer U, Hegemann D, Müller M, Oehr C. Plasma Functionalization of Polypropylene with Acrylic Acid. Surface & Coatings Technology 2003; 174 (none): 805–10. DOI: 10.1016/S0257-8972(03)00564-4.SciarrattaVVohrerUHegemannDMüllerMOehrCPlasma Functionalization of Polypropylene with Acrylic Acid2003174none8051010.1016/S0257-8972(03)00564-4Open DOISearch in Google Scholar
Liu ZM, Xu ZK, Wan LS, Wu J, Ulbricht M. Surface Modification of Polypropylene Microfiltration Membranes by the Immobilization of Poly (N-vinyl-2-pyrrolidone): A Facile Plasma Approach. Journal of Membrane Science 2004; 249(1): 21–31.LiuZMXuZKWanLSWuJUlbrichtMSurface Modification of Polypropylene Microfiltration Membranes by the Immobilization of Poly (N-vinyl-2-pyrrolidone): A Facile Plasma Approach20042491213110.1016/j.memsci.2004.10.001Search in Google Scholar
Hua X, Zhang T, Ren J, Zhang Z, Ji Z, Jiang X, et al. A Facile Approach to Modify Polypropylene Flakes Combining O2-plasmaTreatment and Graft Polymerization of L-lactic Acid. Colloids and Surfaces A: Physicochemical and Engineering Aspects 2010; 369(1): 128–135.HuaXZhangTRenJZhangZJiZJiangXA Facile Approach to Modify Polypropylene Flakes Combining O2-plasmaTreatment and Graft Polymerization of L-lactic Acid2010369112813510.1016/j.colsurfa.2010.08.009Search in Google Scholar
Abednejad AS, Amoabediny G, Ghaee A. Surface Modification of Polypropylene Membrane by Polyethylene Glycol Graft Polymerization. Materials Science & Engineering C 2014; 42(sep.): 443–50.AbednejadASAmoabedinyGGhaeeASurface Modification of Polypropylene Membrane by Polyethylene Glycol Graft Polymerization201442sep.4435010.1016/j.msec.2014.05.060Search in Google Scholar
Hirotsu T. Effects of Oxygen Exposure on Plasma Graft Polymerization of Some Hydrophilic Monomers onto Polypropylene Films. Journal of Macromolecular Science, Part A 1996; 33(11): 1663–74. DOI: 10.1080/10601329608010931.HirotsuTEffects of Oxygen Exposure on Plasma Graft Polymerization of Some Hydrophilic Monomers onto Polypropylene Films1996331116637410.1080/10601329608010931Open DOISearch in Google Scholar
Lin W, Hsieh YL. Ionic Absorption of Polypropylene Functionalized by Surface Grafting and Reactions. Journal of Polymer Science Part A Polymer Chemistry 1997; 35(4): 631–42.LinWHsiehYLIonic Absorption of Polypropylene Functionalized by Surface Grafting and Reactions19973546314210.1002/(SICI)1099-0518(199703)35:4<631::AID-POLA5>3.0.CO;2-SSearch in Google Scholar
Bratskaya S, Marinin D, Nitschke M, Pleul D, Schwarz S, Simon F. Polypropylene Surface Functionalization with Chitosan. Journal of Adhesion Science & Technology 2004; 18(10): 1173–86.BratskayaSMarininDNitschkeMPleulDSchwarzSSimonFPolypropylene Surface Functionalization with Chitosan2004181011738610.1163/1568561041581270Search in Google Scholar
Tsou CH, Yao WH, Hung WS, Suen MC, De Guzman M, Chen J, et al. Innovative Plasma Process of Grafting Methyl Diallyl Ammonium Salt onto Polypropylene to Impart Antibacterial and Hydrophilic Surface Properties. Industrial & Engineering Chemistry Research 2018; 57(7): 2537–45.TsouCHYaoWHHungWSSuenMCDe GuzmanMChenJInnovative Plasma Process of Grafting Methyl Diallyl Ammonium Salt onto Polypropylene to Impart Antibacterial and Hydrophilic Surface Properties201857725374510.1021/acs.iecr.7b04693Search in Google Scholar
Wu Y, Han C, Yang J, Jia S, Wang S. Polypropylene Films Modified by Air Plasma and Feather Keratin Graft. Surface & Coatings Technology 2011; 206(2–3): 506–10.WuYHanCYangJJiaSWangSPolypropylene Films Modified by Air Plasma and Feather Keratin Graft20112062–35061010.1016/j.surfcoat.2011.07.073Search in Google Scholar
Ma WX, Li YG, Pu C, Wu YL. Immobilization of Functional Biomolecules onto Polypropylene Fabric Using Plasma Pre-treatment. Journal of Engineered Fibers and Fabrics 2020; 15(6): DOI: 10.1177/1558925020 978651.MaWXLiYGPuCWuYLImmobilization of Functional Biomolecules onto Polypropylene Fabric Using Plasma Pre-treatment202015610.1177/1558925020 978651Open DOISearch in Google Scholar
Kathavarayan T, Je YY. Enhanced Solubility of Piperine Using Hydrophilic Carrier-based Potent Solid Dispersion Systems. Drug Development and Industrial Pharmacy 2017; 43(9): 1–32. DOI:10.1080/03639045.2017.1321658.KathavarayanTJeYYEnhanced Solubility of Piperine Using Hydrophilic Carrier-based Potent Solid Dispersion Systems201743913210.1080/03639045.2017.132165828425323Open DOISearch in Google Scholar
Jahangiri A, Møller AH, Danielsen M, Madsen B, Joernsgaard B, Vaerbak S, et al. Hydrophilization of Bixin by Lipase-catalyzed Transesterification with Sorbitol. Food Chemistry 2018; 268(DEC.1): 203–9.JahangiriAMøllerAHDanielsenMMadsenBJoernsgaardBVaerbakSHydrophilization of Bixin by Lipase-catalyzed Transesterification with Sorbitol2018268DEC.1203910.1016/j.foodchem.2018.06.08530064749Search in Google Scholar
Renuka R, Ziad ER. Polar Silica-based Stationary Phases. Part II- Neutral Silica Stationary Phases with Surface Bound Maltose and Sorbitol for Hydrophilic Interaction Liquid Chromatography. Journal of Chromatography A 2017; 1508: 24–32.RenukaRZiadERPolar Silica-based Stationary Phases. Part II- Neutral Silica Stationary Phases with Surface Bound Maltose and Sorbitol for Hydrophilic Interaction Liquid Chromatography20171508243210.1016/j.chroma.2017.05.05928599861Search in Google Scholar
Peng B, Li Y, Yang J. Evaluation of Specific Volume, Texture, Thermal Features, Water Mobility, and Inhibitory Effect of Staling in Wheat Bread Affected by Maltitol. Food Chemistry 2019; 283(JUN.15): 123–130.PengBLiYYangJEvaluation of Specific Volume, Texture, Thermal Features, Water Mobility, and Inhibitory Effect of Staling in Wheat Bread Affected by Maltitol2019283JUN.1512313010.1016/j.foodchem.2019.01.04530722851Search in Google Scholar
Rice T, Zannini E, Arendt EK, Coffey A. A Review of Polyols – Biotechnological Production, Food Applications, Regulation, Labeling and Health Effects. Critical Reviews in Food Science and Nutrition 2019(3): 1–18. DOI:10.1080/10408398.2019.1625859.RiceTZanniniEArendtEKCoffeyAA Review of Polyols – Biotechnological Production, Food Applications, Regulation, Labeling and Health Effects2019311810.1080/10408398.2019.162585931210053Open DOISearch in Google Scholar
Vigo TL, Bruno JS. Improvement of Various Properties of Fiber Surfaces Containing Crosslinked Polyethylene Glycols. Journal of Applied Polymer Science 1989; 37(2): 371–9.VigoTLBrunoJSImprovement of Various Properties of Fiber Surfaces Containing Crosslinked Polyethylene Glycols1989372371910.1002/app.1989.070370206Search in Google Scholar
Takke V, Behary N, Perwuelz A, Campagne C. Surface and Adhesion Properties of Poly(Ethylene Glycol) on Polyester(Polyethylene Terephthalate) Fabric Surface: Effect of Air-atmospheric Plasma Treatment. Journal of Applied Polymer Science 2011; 122(4): 2621–9.TakkeVBeharyNPerwuelzACampagneCSurface and Adhesion Properties of Poly(Ethylene Glycol) on Polyester(Polyethylene Terephthalate) Fabric Surface: Effect of Air-atmospheric Plasma Treatment201112242621910.1002/app.34403Search in Google Scholar
Kolate A, Baradia D, Patil S, Vhora I, Kore G, Misra A. PEG — A Versatile Conjugating Ligand for Drugs and Drug Delivery Systems. Journal of Controlled Release 2014; 192: 67–81.KolateABaradiaDPatilSVhoraIKoreGMisraAPEG — A Versatile Conjugating Ligand for Drugs and Drug Delivery Systems2014192678110.1016/j.jconrel.2014.06.04624997275Search in Google Scholar
Pasad DM, Beck KR, Vail SL. Influence of Reagent Residues and Catalysts on Formaldehyde Release from DMDHEU-treated Cotton. Journal of Applied Polymer Science 1987; 34(2): 549–58.PasadDMBeckKRVailSLInfluence of Reagent Residues and Catalysts on Formaldehyde Release from DMDHEU-treated Cotton19873425495810.1002/app.1987.070340210Search in Google Scholar
El-tahlawy KF, El-bendary MA, Elhendawy AG, Hudson SM. The Antimicrobial Activity of Cotton Fabrics Treated with Different Crosslinking Agents and Chitosan. Carbohydrate Polymers 2005; 60(4): 421–30.El-tahlawyKFEl-bendaryMAElhendawyAGHudsonSMThe Antimicrobial Activity of Cotton Fabrics Treated with Different Crosslinking Agents and Chitosan20056044213010.1016/j.carbpol.2005.02.019Search in Google Scholar
Lewis DM, Zhao X, Tapley KN. A New Agent for Cotton Durable Press Finishing under Alkaline Conditions. Aatcc Review. 2002; 2(9): 38–41.LewisDMZhaoXTapleyKNA New Agent for Cotton Durable Press Finishing under Alkaline Conditions2002293841Search in Google Scholar
Tian H, Zhai Y, Xu C, Liang J. Durable Antibacterial Cotton Fabrics Containing Stable Acyclic N-Halamine Groups. Industrial & Engineering Chemistry Research 2017: acs.iecr. 7b00863.TianHZhaiYXuCLiangJDurable Antibacterial Cotton Fabrics Containing Stable Acyclic N-Halamine Groups2017acs.iecr. 7b0086310.1021/acs.iecr.7b00863Search in Google Scholar
Saffari M, Khoddami A, Mallakpour S. The Effect of a Novel Booster (Bisulfate Adduct of Polyisocyanate) on Fluorocarbon Chain Re-orientation and Substrate Properties: Synthesis and finishing. Progress in Organic Coatings 2015; 78: 261–4.SaffariMKhoddamiAMallakpourSThe Effect of a Novel Booster (Bisulfate Adduct of Polyisocyanate) on Fluorocarbon Chain Re-orientation and Substrate Properties: Synthesis and finishing201578261410.1016/j.porgcoat.2014.08.010Search in Google Scholar
Yao J, Lewis DM. Covalent Fixation of Hydroxyethyl Sulphone Dye on Cotton by the Use of Crosslinking Agent Via a Pad-batch Process. Coloration Technology 2010; 116 (7–8): 198–203.YaoJLewisDMCovalent Fixation of Hydroxyethyl Sulphone Dye on Cotton by the Use of Crosslinking Agent Via a Pad-batch Process20101167–819820310.1111/j.1478-4408.2000.tb00038.xSearch in Google Scholar
Dehabadi VA, Buschmann HJ, Gutmann JS. Durable Press Finishing of Cotton Fabrics: An overview. Textile Research Journal. 2013; 83(18): 1974–1995.DehabadiVABuschmannHJGutmannJSDurable Press Finishing of Cotton Fabrics: An overview201383181974199510.1177/0040517513483857Search in Google Scholar
Zeeman R, Dijkstra PJ, Wachem PBv, Luyn M, Fe Ijen J. Successive Epoxy and Carbodiimide Cross-linking of Dermal Sheep Collagen. Biomaterials 1999; 20 (10): 921–31.ZeemanRDijkstraPJWachemPBvLuynMFe IjenJSuccessive Epoxy and Carbodiimide Cross-linking of Dermal Sheep Collagen199920109213110.1016/S0142-9612(98)00242-7Search in Google Scholar
Jung S, Kang S, Kuwabara J, Yoon HJ. Aziridine-based Polyaddition, Post-modification, and Crosslinking: Can Aziridine Rival Epoxide in Polymer Chemistry? Polymer Chemistry 2019; 33(10): 4506–4512.JungSKangSKuwabaraJYoonHJAziridine-based Polyaddition, Post-modification, and Crosslinking: Can Aziridine Rival Epoxide in Polymer Chemistry?201933104506451210.1039/C9PY00979ESearch in Google Scholar
Sweeney JB. Aziridines: Epoxides’ Ugly Cousins? Chemical Society Reviews 2002; 31(5): 247–58.SweeneyJBAziridines: Epoxides’ Ugly Cousins?20023152475810.1039/B006015L12357722Search in Google Scholar
Robinson MWC, Buckle R, Mabbett I, Grant GM, Graham AE. Mesoporous Aaluminosilicate Promoted Alcoholysis of Epoxides. Tetrahedron Letters 2007; 48(42): 4723–4725.RobinsonMWCBuckleRMabbettIGrantGMGrahamAEMesoporous Aaluminosilicate Promoted Alcoholysis of Epoxides200748424723472510.1016/j.tetlet.2007.05.010Search in Google Scholar
Kurmaev EZ, Shin S, Watanabe M, Eguchi R, Ishiwata Y, Takeuchi T, et al. Probing Oxygen and Nitrogen Bonding Sites in Chitosan by X-ray Emission. Journal of Electron Spectroscopy & Related Phenomena 2002; 125(2): 133–8.KurmaevEZShinSWatanabeMEguchiRIshiwataYTakeuchiTProbing Oxygen and Nitrogen Bonding Sites in Chitosan by X-ray Emission20021252133810.1016/S0368-2048(02)00094-4Search in Google Scholar
Li XQ, Tang RC, Teramoto N. Crosslinked and Dyed Chitosan Fiber Presenting Enhanced Acid Resistance and Bioactivities. Polymers 2016; 8(4): 119.LiXQTangRCTeramotoNCrosslinked and Dyed Chitosan Fiber Presenting Enhanced Acid Resistance and Bioactivities20168411910.3390/polym8040119643223430979211Search in Google Scholar
Vandencasteele N. Surface Treatment with Atmospheric Plasma. Adhesives & Sealants Industry 2020; 27(1): 20–5.VandencasteeleNSurface Treatment with Atmospheric Plasma2020271205Search in Google Scholar
Mrsic I, Buerle T, Ulitzsch S, et al. Oxygen Plasma Surface Treatment of Polymer Films—Pellethane 55DE and EPR-g-VTMS. Applied Surface Science 2021; 536: 147782.MrsicIBuerleTUlitzschSOxygen Plasma Surface Treatment of Polymer Films—Pellethane 55DE and EPR-g-VTMS202153614778210.1016/j.apsusc.2020.147782Search in Google Scholar
Elçi Ölçenoğlu G, Saka C. Surface Modification of Coal Sample with Oxygen Plasma Treatment. Surface Engineering 2020; 36(5): 531–8.Elçi ÖlçenoğluGSakaCSurface Modification of Coal Sample with Oxygen Plasma Treatment2020365531810.1080/02670844.2019.1693753Search in Google Scholar
Wei P, Lou H, Xu X. Preparation of PP Non-woven Fabric with Good Heavy Metal Adsorption Performance Via Plasma Modification And Graft Polymerization. Applied Surface Science 2021; 539: 148195.WeiPLouHXuXPreparation of PP Non-woven Fabric with Good Heavy Metal Adsorption Performance Via Plasma Modification And Graft Polymerization202153914819510.1016/j.apsusc.2020.148195Search in Google Scholar
Ma W X, Zhao C, Okubayashi S, et al. A Novel Method of Modifying Poly(ethylene terephthalate) Fabric Using Supercritical Carbon Dioxide. Journal of Applied Polymer Science 2010; 117(4): 1897–1907.MaW XZhaoCOkubayashiSA Novel Method of Modifying Poly(ethylene terephthalate) Fabric Using Supercritical Carbon Dioxide201011741897190710.1002/app.32030Search in Google Scholar
Qla B, Nan Z C, Ln A, et al. One-pot High Efficiency Low Temperature Ultrasonic-assisted Strategy for Fully Bio-based Coloristic, Anti-pilling, Antistatic, Bioactive and Reinforced Cashmere Using Grape Seed Proanthocyanidins. Journal of Cleaner Production 2021; 315: 128148.QlaBNanZ CLnAOne-pot High Efficiency Low Temperature Ultrasonic-assisted Strategy for Fully Bio-based Coloristic, Anti-pilling, Antistatic, Bioactive and Reinforced Cashmere Using Grape Seed Proanthocyanidins202131512814810.1016/j.jclepro.2021.128148Search in Google Scholar