irdpt-140502291914050229195449CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagIran Polymer Technology, Research and Developmentirdpt2538-33451219202383MahmoudHeydari1219202351310.66224/irdpt.45126.8.3.5http://irdpt.ir/fa/Article/45126http://irdpt.ir/fa/Article/Download/45126http://irdpt.ir/fa/Article/Download/45126http://irdpt.ir/fa/Article/Download/45126http://irdpt.ir/fa/Article/Download/45126http://irdpt.ir/fa/Article/Download/45126http://irdpt.ir/fa/Article/Download/45126http://irdpt.ir/fa/Article/Download/451261. Golubev A.Neshitova A.Singin P.Kuvshinova S.Burmistrov V.,Koifman O., Plasticization of Cellulose Nitrate by 4-Nitrophtalic Acid Esters, Russian Journal of General Chemistry, 87, 3086-3092, 2017.2. Kim S.T.Lim J.Y.Choi H.J.,Hyun H., Solution Characteristics of Nitrocellulose, Journal of Industrial and Engineering Chemistry, 12(1), 161-164, 2006.3. Kotter L.N. ,Groven L.J., Hansen Solubility Parameters of Nitrocellulose and Application toward Printable Energetics, Langmuir, 38(29), 8766-8772, 2022.4. Mattar H.Baz Z.Saleh A.Shalaby A.Azzazy A.E.Salah H.,Ismail I., Nitrocellulose: Structure, Synthesis, Characterization, and Applications, Water Energy Food Environ. J, 3, 1-15, 2020.5. Sule R.Rivera G.,Gomes A.V., Western Blotting (Immunoblotting): History, Theory, Uses, Protocol and Problems, BioTechniques, (0), 2023.6. Fernández J.G.Almeida C.A.Fernández-Baldo M.A.Felici E.Raba J.,Sanz M.I., Development of Nitrocellulose Membrane Filters Impregnated with Different Biosynthesized Silver Nanoparticles Applied to Water Purification, Talanta, 146, 237-243, 2016.7. Kuracina R.Szabová Z.Kosár L.,Sahul M., Study into Influence of Different Types of Igniters on the Explosion Parameters of Dispersed Nitrocellulose Powder, Journal of Loss Prevention in the Process Industries, 83, 105017, 2023.8. Frem D., A Reliable Method for Predicting the Specific Impulse of Chemical Propellants, Journal of Aerospace Technology and Management, 10, 2018.9. Carter R. ,Warren R., Extrusion Stresses, Die Swell, and Viscous Heating Effects in Double‐Base Propellants, Journal of Rheology, 31(2), 151-173, 1987.10. Bobić N.Totovski L.Jelisavac L.Nikolić J.Bošnjakov M.R.Marković S.,Drmanić S., The Gelatinization of Nitrocellulose by Primary Stabilizers, Advanced Technologies, 6(2), 31-37, 2017.11. Warren R., The Effect of Ageing and Annealing on the Physical Properties of Nitrocellulose Plasticized with Nitroglycerine, Polymer, 31(5), 861-868, 1990.12. Martínez-Pastor J.Franco P.Moratilla D.,Lopez-Garcia P.J., Optimization of Forming Processes for Gelled Propellant Manufacturing, Modeling and Simulation in Industrial Engineering, 1-28, 2018.13. Warren R.C., Basic Rheology and Its Application to Nitrocellulose Propellant Processing by Screw Mix-Extruders. 1990: Department of Defence, Defence Science and Technology Organisation.14. Dombe G.Mehilal D.Bhongale C.Singh P.P.,Bhattacharya B., Application of Twin Screw Extrusion for Continuous Processing of Energetic Materials, Central European Journal of Energetic Materials, 12(3), 507-522, 2015.15. Hu Q.Gu H.Zhang H.Li C.Ying S.,Xiao Z., Comparative Study on the Rheological Properties of Cellulose Acetate and Double‐Base Propellant, Propellants, Explosives, Pyrotechnics, e202300071.16. Birinci E.Gevgilili H.Kalyon D.M.Greenberg B.Fair D.F.,Perich A., Rheological Characterization of Nitrocellulose Gels, Journal of Energetic Materials, 24(3), 247-269, 2006.17. Solovov R.Kazberova A.,Ershov B., Special Aspects of Nitrocellulose Molar Mass Determination by Dynamic Light Scattering, Polymers, 15(2), 263, 2023.18. Baker F.Healey M.,Privett G., The Rheological Properties of Plasticized Nitrocellulose as a Function of Nitrocellulose Precursor, Propellants, Explosives, Pyrotechnics, 13(4), 99-102, 1988.19. Warren R., The Effect of Liquid Crystal Structure on the Rheological Properties of Nitrocellulose-Dimethylacetamide Solutions, Rheologica acta, 23, 544-547, 1984.20. Baker F.Carter R.,Warren R., The Rheological Assessment of Propellants, in Rheology: Volume 3: Applications. 1980, Springer. p. 591-596.21. Mao C.F. ,Chen C.H., Thermoreversible Gelation of Nitrocellulose Solutions, Journal of Applied Polymer Science, 90(14), 4000-4008, 2003.22. Martinez-Pastor J.Franco P.,Ramirez-Fernandez F.J. Rheological Characterization of Energetic Materials by Rotational Testing Techniques. in Engineering Systems Design and Analysis. 2014. American Society of Mechanical Engineers.23. Chin R.J.Lai S.H.Ibrahim S.,Wan Jaafar W.Z., Factors Affect Wall Slip: Particle Size, Concentration, and Temperature, Applied Rheology, 28(1), 201815775, 2018.24. Kalyon D.M., An Overview of the Rheological Behavior and Characterization of Energetic Formulations: Ramifications on Safety and Product Quality, Journal of Energetic Materials, 24(3), 213-245, 2006.25. Martinez-Pastor J.Franco P.Ramirez F.,Lopez-Garcia P., Experimental Analysis of Rheological Behaviour of a Multi-Base Energetic Material During Non-Continuous Mixing, Procedia engineering, 132, 366-372, 2015.26. Martinez-Pastor J.Franco P.,Franco-Menchon J., Optimization of Extrusion Process of Double-Base Propellants from Their Rheological Properties, International Journal of Material Forming, 12, 307-320, 2019.27. Martinez-Pastor J.Franco P.Ramirez F.,Lopez-Garcia P., Experimental Analysis of Rheological Behaviour of a Multi-Base Energetic Material During Conventional Extrusion, Procedia Engineering, 132, 373-380, 2015.28. Martinez-Pastor J.Franco P.Ramirez F.J.,Lopez-Garcia P.J., Influence of Rheological Behaviour on Extrusion Parameters During Non-Continuous Extrusion of Multi-Base Propellants, International Journal of Material Forming, 11, 87-99, 2018.MiladGhaniMarziyehKavian12192023152410.66224/irdpt.45127.8.3.15http://irdpt.ir/fa/Article/45127http://irdpt.ir/fa/Article/Download/45127http://irdpt.ir/fa/Article/Download/45127http://irdpt.ir/fa/Article/Download/45127http://irdpt.ir/fa/Article/Download/45127http://irdpt.ir/fa/Article/Download/45127http://irdpt.ir/fa/Article/Download/45127http://irdpt.ir/fa/Article/Download/45127[1] Cote A. P., Benin A. I., Ockwig N. W., O'Keeffe M., Matzger A. J., & Yaghi O. M., Porous, crystalline, covalent organic frameworks, science, 310, 1166-1170, 2005.[2] Lyu H., Ji, Z., Wuttke S., & Yaghi O. M., Digital reticular chemistry, Chem, 6, 2219-2241, 2020.[3] Ding M., Flaig R. W., Jiang H. L., & Yaghi O. M., Carbon capture and conversion using metal–organic frameworks and MOF-based materials, Chemical Society Reviews, 48, 2783-2828, 2019.[4] Cai G., Yan P., Zhang L., Zhou H. C., & Jiang H. L., Metal–organic framework-based hierarchically porous materials: synthesis and applications, Chemical Reviews, 121, 12278-12326, 2021.[4] Tian Y., & Zhu G., Porous aromatic frameworks (PAFs), Chemical reviews, 120, 8934-8986, 2020.[6] Furukawa H., Cordova K. E., O’Keeffe M., & Yaghi O. M., The chemistry and applications of metal-organic frameworks, Science, 341, 1230444, 2013.[7] Geng K., He T., Liu R., Dalapati S., Tan K. T., Li Z., & Jiang D., Covalent organic frameworks: design, synthesis, and functions, Chemical Reviews, 120, 8814-8933, 2020.[8] Dong J., Tan C., Zhang K., Liu Y., Low P. J., Jiang J., & Cui Y., Chiral NH-controlled supramolecular metallacycles, Journal of the American Chemical Society, 139, 1554-1564, 2017.[9] Yaghi O. M., & Li, H., Hydrothermal synthesis of a metal-organic framework containing large rectangular channels, Journal of the American Chemical Society, 117, 10401-10402, 1995.[10] Chowdhury P., Bikkina C., & Gumma S., Gas adsorption properties of the chromium-based metal organic framework MIL-101, The Journal of Physical Chemistry C, 113, 6616-6621, 2009.[11] Ding S. Y., & Wang W., Covalent organic frameworks (COFs): from design to applications, Chemical Society Reviews, 42, 548-568, 2013.[12] Kang I. J., Khan N. A., HaqueE., & Jhung S. H., Chemical and thermal stability of isotypic metal–organic frameworks: effect of metal ions, Chemistry–A European Journal, 17, 6437-6442, 2011.[13] Cui J., Feng Y., & Jia S., Silica encapsulated catalase@ metal-organic framework composite: A highly stable and recyclable biocatalyst, Chemical Engineering Journal, 351, 506-514, 2018.[14] Ding M., & Jiang H. L., Improving water stability of metal–organic frameworks by a general surface hydrophobic polymerization, CCS Chemistry, 3, 2740-2748, 2021.[15] Li Y. M., Yuan J., Ren H., Ji C. Y., Tao Y., Wu Y., & Cheng L., Fine-tuning the micro-environment to optimize the catalytic activity of enzymes immobilized in multivariate metal–organic frameworks, Journal of the American Chemical Society, 143, 15378-15390, 2021.[16] Ma M., Lu X., Guo Y., Wang L., & Liang X., Combination of metal-organic frameworks (MOFs) and covalent organic frameworks (COFs): Recent advances in synthesis and analytical applications of MOF/COF composites, TrAC Trends in Analytical Chemistry, 116741, 2022.[17] Peng Y., Zhao M., Chen B., Zhang Z., Huang Y., Dai F., & Zhang H., Hybridization of MOFs and COFs: a new strategy for construction of MOF@ COF core–shell hybrid materials, Advanced materials, 30, 1705454, 2018.[18] Feng L., Wang K. Y., Lv X. L., Yan T. H., Li J. R., & Zhou H. C., Modular total synthesis in reticular chemistry, Journal of the American Chemical Society, 142, 3069-3076, 2020.[19] Li F., Wang D., Xing Q. J., Zhou G., Liu S. S., Li Y., & Zou J. P., Design and syntheses of MOF/COF hybrid materials via postsynthetic covalent modification: An efficient strategy to boost the visible-light-driven photocatalytic performance, Applied Catalysis B: Environmental, 243, 621-628, 2019.[20] He S., Rong Q., Niu H., & Cai Y. Platform for molecular-material dual regulation: A direct Z-scheme MOF/COF heterojunction with enhanced visible-light photocatalytic activity, Applied Catalysis B: Environmental, 247, 49-56, 2019.[21] Zhang F. M., Sheng J. L., Yang Z. D., Sun X. J., Tang H. L., Lu M., & Lan Y. Q., Rational design of MOF/COF hybrid materials for photocatalytic H2 evolution in the presence of sacrificial electron donors, Angewandte Chemie International Edition, 57, 12106-12110, 2018.[22] Sun D., & Kim D. P., Hydrophobic MOFs@ metal nanoparticles@ COFs for interfacially confined photocatalysis with high efficiency, ACS applied materials & interfaces, 12, 20589-20595, 2020.[23] Sun W., Tang X., Yang Q., Xu Y., Wu F., Guo S., & Wang Y. Coordination‐induced interlinked covalent‐and metal–organic‐framework hybrids for enhanced lithium storage, Advanced Materials, 31, 1903176, 2019.[24] Firoozi M., Rafiee Z., & Dashtian, K. New MOF/COF hybrid as a robust adsorbent for simultaneous removal of auramine O and rhodamine B dyes, ACS omega, 5, 9420-9428, 2020.[25] Das S., Ben T., Qiu S., & Valtchev V., Two-dimensional COF–three-dimensional MOF dual-layer membranes with unprecedentedly high H2/CO2 selectivity and ultrahigh gas permeabilities, ACS Applied Materials & Interfaces, 12, 52899-52907, 2020.[26] Liu X., Hu M., Wang M., Song Y., Zhou N., He L., & Zhang Z., Novel nanoarchitecture of Co-MOF-on-TPN-COF hybrid: Ultralowly sensitive bioplatform of electrochemical aptasensor toward ampicillin, Biosensors and Bioelectronics, 123, 59-68, 2019.[27] Li M., Qiao S., Zheng Y., Andaloussi Y. H., Li, X., Zhang Z., & Chen Y., Fabricating covalent organic framework capsules with commodious microenvironment for enzymes, Journal of the American Chemical Society, 142, 6675-6681, 2020.HamidrezaHaydariMarziyehHosseini12192023253710.66224/irdpt.45128.8.3.25http://irdpt.ir/fa/Article/45128http://irdpt.ir/fa/Article/Download/45128http://irdpt.ir/fa/Article/Download/45128http://irdpt.ir/fa/Article/Download/45128http://irdpt.ir/fa/Article/Download/45128http://irdpt.ir/fa/Article/Download/45128http://irdpt.ir/fa/Article/Download/45128http://irdpt.ir/fa/Article/Download/451281. Lester B, Vernon B, Vernon HM. “Process of Manufacturing Articles of Thermoplastic Synthetic Resins”, US Pat 2234993, 1941.2. J. Hu, Y. Zhu, H. Huang, J. Lu, “Recent Advances in Shape-Memory Polymers: Structure, Mechanism, Functionality, Modeling and Applications”, Prog. Polym. Sci, 37, 1720-1763, 2012.3. Rainer WC, Redding EM, Hitov JJ, Sloan AW, Stewart WD. “Polyethylene Product and Process”, US Pat 3144398, 1964.4.¬ Sokolowski W. “Lightweight Shape Memory Self-Deployable Structures for Gossamer Applications”, In: 45th AIAA/ASME Structures, Structural Dynamic and Materials Conference, 2004.5. Wang ZL, Kang ZC. “Functional and Smart Materials”, New York: Plenum Publishing Corp, pp.514, 1998.6. Maksimkin, A.V.; Dayyoub, T.; Telyshev, D.V.; Gerasimenko, A.Y. “Electroactive Polymer-Based Composites for Artificial Musclelike Actuators: A Review”. Nanomaterials, 12, 2272, 2022.7. Hu JL, Chen SJ. “A Review of Actively Moving Polymers in Textile Applications”, Journal of Materials Chemistry, 20, 3346-3355, 2010.8. Chen, Y.; Chen, C.; Rehman, H.U.; Zheng, X.; Li, H.; Liu, H.; Hedenqvist, M.S. “Shape-Memory Polymeric Artificial Muscles: Mechanisms, Applications and Challenges”. Molecules, 25, 4246, 2020.9. Cao, L.; Wang, L.; Zhou, C.; Hu, X.; Fang, L.; Ni, Y.; Fang, L.; Ni, Y.; Lu, C.; Xu, Z. “Surface Structures, Particles, and Fibers of Shape-Memory Polymers at Micro-/Nanoscale”. Adv. Polym. Technol, 7639724, 2020.10. Lendlein, A.; Kelch, S. “Shape-Memory Polymers”. Angew. Chem. Int. Ed. 41, 2034–2057, 2002.[11] Lendlein A, Kelch S. “Shape-memory polymers”, Angewandte Chemie-International Edition, 41, 2034-2057, 2002.12. M. Behl and A. Lendlein, “Actively Moving Polymers”, Soft Matter, 3, 58-67, 2007.13. Li JH, Viveros JA, Wrue MH, Anthamatten M. “Shape-memory Effects in Polymer Networks Containing Reversibly Associating Side-groups”, Advanced Materials, 19, 2851-2855, 2007.14. Zhang S, Yu ZJ, Govender T, Luo HY, Li BJ. “A Novel Supramolecular Shape Memory Material Based on Partial Alpha-CD-PEG Inclusion Complex”, Polymer, 49, 3205-3210, 2008.15. Hu JL, Chen SJ. “A Review of Actively Moving Polymers in Textile Applications”, Journal of Materials Chemistry, 20, 3346-3355, 2010.16. Zhu Y, Hu JL, Luo HS, Young RJ, Deng LB, Zhang S, Fan Y, Ye GD. “Rapidly Switchable Water-Sensitive Shape-Memory Cellulose/Elastomer Nano-Composites”, Soft Matter, 8, 2509-2517, 2012.17. D’Hollander S, Van Assche G, Van Mele B, Du Prez F. “Novel Synthetic Strategy Toward Shape Memory Polyurethanes With a Well-Defined Switching Temperature”, Polymer, 50, 4447–54, 2009.18. Rousseau IA,Mather PT. “Shape-memory Effect Exhibited by Smectic Liquid Crystalline Elastomers”, Journal of the American Chemical Society, 125, 15300-15301, 2003.19. A. Lendlein, H. Jiang, O. Junger, and R. Langer, “Light-Induced Shape-Memory Polymers”, Nature, 434, 879-882, 2005.20. L. Wu, C. Jin, and X. Sun, “Synthesis, Properties, and Light-Induced Shape Memory Effect of Multiblock Polyesterurethanes Containing Biodegradable Segments and Pendant Cinnamamide Groups”, Biomacromolecules, 12, 235-241, 2011.21. B. Yang, W. M. Huang, C. Li, and L. Li, “Effects of Moisture on the Thermomechanical Properties of a Polyurethane Shape Memory Polymer”, Polymer (Guildf), 47, 1348-1356, 2006.22. Y. Zhu, J. Hu, H. Luo, R. J. Young, L. Deng, S. Zhang, Y. Fan, and G. Ye, “Rapidly Switchable Water-Sensitive Shape-Memory Cellulose/Elastomer Nano-Composites”, Soft Matter, 8, 2509-2517, 2012.23. Miaudet P, Derre A, Maugey M, Zakri C, Piccione PM, Inoubli R, Poulin P. “Shape and Temperature Memory of Nanocomposites with Broadened Glass Transition”, Science, 318, 1294–6, 2007.24. Meng QH, Hu JL, Zhu Y, Lu J, Liu Y. “Polycaprolactone-Based Shape Memory Segmented Polyurethane Fiber”, Journal of Applied Polymer Science, 106, 2515-2523, 2007.25. Jung YC, Cho JW. “Application of Shape Memory Polyurethane in Orthodontic”, Journal of Materials Science: Materials in Medicine, 21, 2881-2886, 2010.26. Yakacki CM, Shandas R, Lanning C, Rech B, Eckstein A, Gall K. “Unconstrained Recovery Characterization of Shape-memory Polymer Networks for Cardiovascular Applications”, Biomaterials, 28, 2255–2263, 2007.27. Tang, L., Wang, Y., Zhou, T., Li, Y., & Li, Q. “Enhanced Toughness and Mechanical Property of Epoxy Resins with Good Shape Memory Behaviors”, Fibers and Polymers, 21, 1187-1194, 2020.28. Rao, Kavitha V., G. S. Ananthapadmanabha, and G. N. Dayananda. “Effect of Cross-Linking Density on Creep and Recovery Behavior in Epoxy-Based Shape Memory Polymers (SMEPs) for Structural Applications”, Journal of Materials Engineering and Performance, 25, 5314-5322, 2016.29. Jing, Xianghai, et al. “Toughening‐Modified Epoxy‐Amine System: Cure Kinetics, Mechanical Behavior, and Shape Memory Performances”, Journal of Applied Polymer Science, 131, 40853, 2014.30. Wang, L., Zhang, F., Liu, Y., & Leng, J. “Shape Memory Polymer Fibers: Materials, Structures, and Applications”, Advanced Fiber Materials, 4, 5-23, 2022.31. Xue, J., Xie, J., Liu, W., & Xia, Y. “Electrospun Nanofibers: New Concepts, Materials, and Applications”, Accounts of chemical research, 50, 1976-1987, 2017.32. Zhang, F., Zhang, Z., Liu, Y., Cheng, W., Huang, Y., & Leng, J. “Thermosetting Epoxy Reinforced Shape Memory Composite Microfiber Membranes: Fabrication, Structure and Properties”, Composites Part A: Applied Science and Manufacturing, 76, 54-61, 2015.33. Wu, Jinglei, and Yi Hong. “Enhancing Cell Infiltration of Electrospun Fibrous Scaffolds in Tissue Regeneration”, Bioactive materials, 1, 56-64, 2016.34. Zhang, Z., Zhang, F., Jiang, X., Liu, Y., Guo, Z., & Leng, J. “Electrospinning and Microwave Absorption of Polyaniline/Polyacrylonitrile/Multiwalled Carbon Nanotubes Nanocomposite Fibers”, Fibers and Polymers, 15, 2290-2296, 2014.35. Liao, Y., Loh, C. H., Tian, M., Wang, R., & Fane, A. G. “Progress in Electrospun Polymeric Nanofibrous Membranes for Water Treatment: Fabrication, Modification and Applications”, Progress in Polymer Science, 77, 69-94, 2018.[36] Loke, G., Alain, J., Yan, W., Khudiyev, T., Noel, G., Yuan, R., & Fink, Y. “Computing Fabrics”, Matter, 2, 786-788, 2020.[37] Yan, W., Richard, I., Kurtuldu, G., James, N. D., Schiavone, G., Squair, J. W., & Sorin, F. “Structured Nanoscale Metallic Glass Fibres with Extreme Aspect Ratios”, Nature nanotechnology, 15, 875-882, 2020.[38] Loke, G., Yan, W., Khudiyev, T., Noel, G., & Fink, Y. “Recent Progress and Perspectives of Thermally Drawn Multimaterial Fiber Electronics”, Advanced Materials, 32, 1904911, 2020.[39] Yan, W., Dong, C., Xiang, Y., Jiang, S., Leber, A., Loke, G, & Tao, G. “Thermally Drawn Advanced Functional Fibers: New frontier of flexible electronics”, Materials Today, 35, 168-194, 2020.AhdiehAmjadiFereshtehBarragh Jam12192023395110.66224/irdpt.45130.8.3.39http://irdpt.ir/fa/Article/45130http://irdpt.ir/fa/Article/Download/45130http://irdpt.ir/fa/Article/Download/45130http://irdpt.ir/fa/Article/Download/45130http://irdpt.ir/fa/Article/Download/45130http://irdpt.ir/fa/Article/Download/45130http://irdpt.ir/fa/Article/Download/45130http://irdpt.ir/fa/Article/Download/451301. Li Y., Huang X., Zeng L., Li R., Tian, H., Fu X., Wang Y., Zhong W.H. A Review of the Electrical and Mechanical Properties of Carbon Nanofiller-Reinforced Polymer Composites. Journal of Materials Science, 54, 1036–1076, 2019.2. Nurazzi N.M., Sabaruddin F.A., Harussani M.M., Kamarudin S.H., Rayung M., Asyraf M.R.M., Aisyah H.A., Norrrahim M.N.F., Ilyas R.A., Abdullah N., Zainudin E.S., Sapuan S.M., Khalina A., Mechanical Performance and Applications of CNTs Reinforced Polymer Composites-A Review. Nanomaterials (Basel), 11, 2186, 2021. 3. Saifuddin N., Raziah A., and Junizah A., Carbon Nanotubes: A Review on Structure and Their Interaction with Proteins. Journal of Chemistry, 2013, 2013.4. Takakura A., Beppu K., Nishihara T., Strength of Carbon Nanotubes Depends on Their Chemical Structures. Nature Communications, 10, 3040, 2019.5. https://www.fortunebusinessinsights.com/carbon-nanotubes-cnt-market-102700. Available in Nov, 2021.6. Zakaria M. R., Md Akil H., Abdul Kudus M. H., Ullah F., Javed F., Nosbi N., Hybrid Carbon Fiber-Carbon Nanotubes Reinforced Polymer Composites: A Review. Composites Part B: Engineering, 176, 2019.7. Xie S., Li W., Pan Z., Chang B., Sun L., Mechanical and Physical Properties on Carbon Nanotube. Journal of Physics and Chemistry of solids, 61, 1153-1158, 2000.8. Egbo, M.K., A Fundamental Review on Composite Materials and Some of Their Applications in Biomedical Engineering. Journal of King Saud University-Engineering Sciences, 33, 557-568, 2021.9. Kumar A., Sharma K., and Dixit A.R., A Review on the Mechanical Properties of Polymer Composites Reinforced by Carbon Nanotubes and Graphene. Carbon Letters, 31, 149-165, 2021.10. Kumar A., Sharma K., and Dixit A.R., Carbon Nanotube-And Graphene-Reinforced Multiphase Polymeric Composites: Review on Their Properties and Applications. Journal of Materials Science, 55, 2682-2724, 2019.11. Hsissou, R., Seghiri R., Benzekri Z., Hilali M., Polymer Composite Materials: A Comprehensive Review. Composite structures, 262, 113640, 2021.12. Al-Saleh M.H., and Sundararaj U., Review of the Mechanical Properties of Carbon Nanofiber/Polymer Composites. Composites Part A: Applied Science and Manufacturing, 42, 2126-2142, 2011.13. Karthik, K., Rajamani D., Manimaran A., Udayaprakash J., Evaluation of Tensile Properties on Glass/Carbon/Kevlar Fiber Reinforced Hybrid Composites. Materials Today: Proceedings, 39, 1655-1660, 2021.14. Coleman J. N., Khan U., Blau W. J., Gunko Y.K., Small but Strong: A Review of the Mechanical Properties of Carbon Nanotube-Polymer Composites, Carbon, 44, 1624-1652, 2006.15. Mei, H., Xia J., Han D., Xiao S., Deng J., Dramatic Increase in Electrical Conductivity in Epoxy Composites with Uni-Directionally Oriented Laminae of Carbon Nanotubes. Chemical Engineering Journal, 304, 970-976, 2016.16. Mecklenburg M., Mizushima D., Ohtake N., Bauhofer W., Fiedler B., Schulte K., On the Manufacturing and Electrical and Mechanical Properties of Ultra-High Wt.% Fraction Aligned MWCNT and Randomly Oriented CNT Epoxy Composites. Carbon, 91, 275-290, 2015.17. Kalakonda P., and Banne S., Thermomechanical Properties of PMMA and Modified SWCNT Composites. Nanotechnology, science and applications, 10, 45-52, 2017.18. Behera R.P., Rawat P., Tiwari S. K., Singh K. K., A Brief Review on the Mechanical Properties of Carbon Nanotube Reinforced Polymer Composites. Materials Today: Proceedings, 22, 2109-2117, 2020.19. Zhou S., Hrymak A.N., Kamal M.R., Electrical, Thermal, and Mechanical Properties of Polypropylene/Multiwalled Carbon Nanotube Micromoldings. Polymer Composites, 41, 1507-1520, 2020.20. Venkatesan M., Palanikumar K., Boopathy S.R., Experimental Investigation and Analysis on the Wear Properties of Glass Fiber and CNT Reinforced Hybrid Polymer Composites. Science and Engineering of Composite Materials, 25, 963-974, 2018.21. Scaffaro R., and Maio A., Integrated Ternary Bionanocomposites with Superior Mechanical Performance via the Synergistic Role of Graphene and Plasma Treated Carbon Nanotubes. Composites Part B: Engineering, 168, 550-559, 2019.22. Zhang W.D., Shen L., Phang I.Y., Liu T., Carbon Nanotubes Reinforced Nylon-6 Composite Prepared by Simple Melt-Compounding. Macromolecules, 37, 256-259, 2004.23. Tang L.-C., Wan Y.-J., Peng K., Pei Y., Wu, L., Chen L., Shu L., Jiang J., Lai G., Fracture Toughness and Electrical Conductivity of Epoxy Composites Filled with Carbon Nanotubes and Spherical Particles. Composites Part A: Applied Science and Manufacturing, 45, 95-101, 2013.24. Zhang J., Ju S., Jiang D., Peng H., Reducing Dispersity of Mechanical Properties of Carbon Fiber/Epoxy Composites by Introducing Multi-Walled Carbon Nanotubes. Composites Part B: Engineering, 54, 371-376, 2013.25. Zhang W., Picu R., Koratkar N., The Effect of Carbon Nanotube Dimensions and Dispersion on the Fatigue Behavior of Epoxy Nanocomposites. Nanotechnology, 19, 285709, 2008.26. Mousavi S., Alignment of Multi Wall Carbon Nanotube in Epoxy Polymer Matrix and Investigating the Effect of CNT’s Alignment on the Mechanical Properties of Composite. In Proceedings of the Second International Conference on New Approaches in Science, Engineering and Technology, Istanbul, Turkey. 2015.27. Kim S., Jung S., Kim W.-J., Vertical Alignment of Carbon Nanotubes in Photo-Curable Polymer for Multi-Functional Hybrid Materials. Applied Surface Science, 612, 155749, 2023.28. Koirala P., Werken N., Lu H., Baughman R.H., Ovalle-Robles R., Tehrani M., Using Ultra-Thin Interlaminar Carbon Nanotube Sheets to Enhance the Mechanical and Electrical Properties of Carbon Fiber Reinforced Polymer Composites. Composites Part B: Engineering, 216, 108842 2021.29. Boroujeni A.Y. and Al-Haik M., Carbon Nanotube – Carbon Fiber Reinforced Polymer Composites with Extended Fatigue Life. Composites Part B: Engineering, 164, 537-545, 2019.30. Grimmer C.S. and Dharan C.K.H., High-Cycle Fatigue of Hybrid Carbon Nanotube/Glass Fiber/Polymer Composites. Journal of Materials Science, 43, 4487-4492, 2008.31. Davis D.C., Wilkerson J.W., Shu J., Ayewah D., Improvements in Mechanical Properties of A Carbon Fiber Epoxy Composite Using Nanotube Science and Technology. Composite Structures, 92, 2653-2662, 2010.32. Borrego L.P., Costa J.D.M., Ferreira J.A.M., Silva H., Fatigue Behaviour of Glass Fibre Reinforced Epoxy Composites Enhanced with Nanoparticles. Composites Part B: Engineering, 62, 65-72, 2014.33. Yousefi N., Fisher S.J., Burgstaller C. Shaffer M.S.P., Bismarck A., Hierarchical Carbon Fibre Composites Incorporating High Loadings of Carbon Nanotubes. Composites Science and Technology, 222, 109369, 2022.34. Qian H., Greenhalgh E.S., Shaffer M.S.P., Bismarck A., Carbon Nanotube-Based Hierarchical Composites: A Review. Journal of Materials Chemistry, 20, 4751-4762, 2010.35. Lesko J.J., Swain R.E., Cartwright J.M., Chin J.W., Reifsnider K.L., Dillard D.A., Wightman J.P., Interphases Developed from Fiber Sizing’s and Their Chemical-Structural Relationship to Composite Compressive Performance, The Journal of Adhesion, 45, 43-58, 2020.36. Han L., Li k., Xiao C., Yin X., Gui X., Song Q., Ye F., Carbon Nanotube-Vertical Edge Rich Graphene Hybrid Sponge as Multifunctional Reinforcements for High Performance Epoxy Composites. Carbon, 201, 871-880, 2023.37. Liu Y., Li J., Kuang Y., Interlaminar Properties of Carbon Nanotubes Modified Carbon Fibre Fabric Reinforced Polyimide Composites. Journal of Composite Materials, 57, 1277-1288, 2023.38. Jongvivatsakul, P., Thongchom C., Mathuros A., Prasertsri T., Adamu M., Orasutthikul S., Lenwari A., Charainpanitkul T., Enhancing Bonding Behavior Between Carbon Fiber-Reinforced Polymer Plates and Concrete Using Carbon Nanotube Reinforced Epoxy Composites. Case Studies in Construction Materials, 17, 01407, 2022.Mohammad HosseinKaramiMajidAbdoussMandanaKarami12192023536410.66224/irdpt.45131.8.3.53http://irdpt.ir/fa/Article/45131http://irdpt.ir/fa/Article/Download/45131http://irdpt.ir/fa/Article/Download/45131http://irdpt.ir/fa/Article/Download/45131http://irdpt.ir/fa/Article/Download/45131http://irdpt.ir/fa/Article/Download/45131http://irdpt.ir/fa/Article/Download/45131http://irdpt.ir/fa/Article/Download/451311. Kazemi S., Pourmadadi M., Yazdian F., Ghadami A., The Synthesis and Characterization of Targeted Delivery Curcumin Using Chitosan-Magnetite-Reduced Graphene Oxide as Nano-Carrier, Int J Biol Macromol, 186,554-562, 2021.2. Pourmadadi M., Ahmadi MJ., Abdouss M., Yazdian F., Rashedi H., Navaei-Nigjeh M., Hesari Y., The Synthesis and Characterization of Double Nanoemulsion for Targeted Co-Delivery of 5-Fluorouracil and Curcumin Using pH-Sensitive Agarose/Chitosan Nanocarrier, J Drug Deliv Sci Technol,70,102849,2022.3. Omrani Z., Pourmadadi M., Yazdian F., Rashedi H., Preparation and Characterization of PH-Sensitive Chitosan/Starch/MoS2 Nanocomposite For Control Release of Curcumin Macromolecules Drug Delivery; Application in The Breast Cancer Treatment, Int J Biol Macromol, 250,125897, 2023.4. Shakouri S., Pourmadadi M., Abdouss M., Rahdar A., Pandey S., pH-responsive Double Emulsion System for Targeted Anticancer Therapy Based on Polyacrylic Acid-Polyvinyl Pyrrolidone Containing Carbon Nanotubes for 5-Fluorouracil As an Anticancer Medication, Inorg Chem Commun, 158(Part 1),111494,2023.5. Zoghi M., Pourmadadi M., Yazdian F., Navaei Nigjeh M., Rashedi H., Sahraeian R., Synthesis and Characterization of Chitosan/Carbon Quantum Dots/Fe2O3 Nanocomposite Comprising Curcumin For Targeted Drug Delivery in Breast Cancer Therapy, Int J Biol Macromol, 249,125788,2023.6. EshaghiMM., Pourmadadi M., Rahdar A., Díez-Pascual AM., Improving Quercetin Anticancer Activity Through A Novel Polyvinylpyrrolidone/Polyvinyl alcohol/TiO2 Nanocomposite, J Drug Deliv Sci Technol, 81,104304, 2023. 7. Najafabadi AP., Pourmadadi M., Yazdian F., Rashedi H., Rahdar A., Díez-Pascual AM., pH-Sensitive Ameliorated Quercetin Delivery Using Graphene Oxide Nanocarriers Coated With Potential Anticancer Gelatin-Polyvinylpyrrolidone Nanoemulsion With Bitter Almond Oil, J Drug Deliv Sci Technol, 82,104339,2023.8. Rahmani E., Pourmadadi M., Ghorbanian SA., Yazdian F., Rashedi H., Navaee M., Preparation of a PH-Responsive Chitosan-Montmorillonite-Nitrogen-Doped Carbon Quantum Dots Nanocarrier For Attenuating Doxorubicin Limitations in Cancer Therapy, Eng Life Sci. ,22,634-649,2022.9. Abdouss A., Pourmadadi M., Zahedi P., Abdouss M., Yazdian F., Rahdar A., Díez-Pascual AM, Green Synthesis of Chitosan/Polyacrylic Acid/Graphitic Carbon Nitride Nanocarrier As a Potential PH-Sensitive System for Curcumin Delivery to MCF-7 Breast Cancer Cells, Int J Biol Macromol, 242(Part3),125134, 2023.10. Pourmadadi M., Ahmadi MJ., Yazdian F., Synthesis of A Novel PH-Responsive Fe3O4/Chitosan/Agarose Double Nanoemulsion As a Promising Nanocarrier with Sustained Release of Curcumin to Treat MCF-7 Cell Line, Int J Biol Macromol, 235,123786,2023. 11. Bayat F., Pourmadadi M., Eshaghi MM., Improving Release Profile and Anticancer Activity of 5-Fluorouracil for Breast Cancer Therapy Using a Double Drug Delivery System: Chitosan/Agarose/γ-Alumina Nanocomposite@Double Emulsion, J Clust Sci ,34(5),2565-2577,2023.12. Rajaei M., Rashedi H., Yazdian F., Navaei-Nigjeh M., Rahdar A., Díez-Pascual AM., Chitosan/Agarose/Graphene Oxide Nanohydrogel As Drug Delivery System of 5-Fluorouracil in Breast Cancer Therapy, J Drug Deliv Sci Technol, 82,104307,2023.13. Pourmadadi M., Darvishan S., Abdouss M., Yazdian F., Rahdar A., Díez-Pascual AM., PH-Responsive Polyacrylic Acid (PAA)-Carboxymethyl Cellulose (CMC) Hydrogel Incorporating Halloysite Nanotubes (HNT) For Controlled Curcumin Delivery, Ind Crops Prod ,197,116654,2023.14. Ostovar S., Pourmadadi M., Shamsabadipour A., Mashayekh P., Nanocomposite of Chitosan/Gelatin/Carbon Quantum Dots As a Biocompatible and Efficient Nanocarrier For Improving the Curcumin Delivery Restrictions to Treat Brain Cancer, Int J Biol Macromol, ,242(Part 3),124986,2023.15. Gerami AE, Pourmadadi M, Fatoorehchi H, Yazdian F, Rashedi H, Nigjeh MN. Preparation of PH-Sensitive Chitosan/Polyvinylpyrrolidone/α-Fe2O3 Nanocomposite For Drug Delivery Application: Emphasis on Ameliorating Restrictions, Int J Biol Macromol, 173,409-420,2021.16. Samadi A., Pourmadadi M., Yazdian F., Rashedi H., Navaei-Nigjeh M., Eufrasio-da-silva T., Ameliorating Quercetin Constraints in Cancer Therapy with PH-Responsive Agarose-Polyvinylpyrrolidone-Hydroxyapatite Nanocomposite Encapsulated in Double Nanoemulsion, Int J Biol Macromol, 182,11-25,2021.17. Ematollahi E., Pourmadadi M., Yazdian F., Fatoorehchi H., Rashedi H., Navaei Nigjeh M., Synthesis and Characterization of Chitosan/Polyvinylpyrrolidone Coated Nanoporous γ-Alumina As a pH-Sensitive Carrier for Controlled Release of Quercetin, Int J Biol Macromol, 183,600-613,2021.18. Darvishan S., Pourmadadi M., Abdouss M., Mazinani S., Yazdian F., Rahdar A., Díez-Pascual AM., Gamma Alumina Coated-PAA/PVP Hydrogel As Promising Quercetin Nanocarrier: Physiochemical Characterization and Toxicity Activity, J Drug Deliv Sci Technol,84,104500, 2023. 19. Pourmadadi M., Aslani A., Abdouss M., Synthesis and Characterization of Biological Macromolecules Double Emulsion Based on Carboxymethylcellulose/Gelatin Hydrogel Incorporated with ZIF-8 As Metal Organic Frameworks for Sustained Anti-Cancer Drug Release. Int J Biol Macromol, 243,125168,2023.20. jalli N., Pourmadadi M., Yazdian F., Rashedi H., Navaei-Nigjeh M., Díez-Pascual AM., Chitosan/Gamma-Alumina/Fe3O4@5-FU Nanostructures As Promising Nanocarriers: Physiochemical Characterization and Toxicity Activity, Molecules, 27,5369,2022. 21. Darvishan S., Pourmadadi M., Abdouss M., Mazinani S., Yazdian F., Rahdar A., Díez-Pascual AM,. Gamma alumina coated-PAA/PVP Hydrogel As Promising Quercetin Nanocarrier: Physiochemical Characterization and Toxicity Activity, J Drug Deliv Sci Technol, 84,104500,2023. 22. Parvaneh S., Pourmadadi M., Abdouss M., Pourmousavi SA., Yazdian F., Rahdar A., Díez-Pascual AM., Carboxymethyl Cellulose/Starch/Reduced Graphene Oxide Composite As a PH-Sensitive Nanocarrier For Curcumin Drug Delivery, Int J Biol Macromol,241,124566,2023.23. Eshaghi M., Pourmadadi M., Rahdar A., Díez-Pascual AM., Novel Carboxymethyl Cellulose-Based Hydrogel with Core–Shell Fe3O4@SiO2 Nanoparticles for Quercetin Delivery,Materials,15,8711,2022.24. Ahmadi MJ., Pourmadadi M., Ghorbanian SA., Yazdian F., Rashedi H., Ultra PH-Sensitive Nanocarrier Based on Fe2O3/Chitosan/Montmorillonite for Quercetin Delivery, Int J Biol Macromol,191,738-745, 2021.25. Haseli S., Pourmadadi M., Samadi A., A Novel pH-Responsive Nanoniosomal Emulsion for Sustained Release of Curcumin From a Chitosan-Based Nanocarrier: Emphasis on the Concurrent Improvement of Loading, Sustained Release, and Apoptosis Induction, Biotechnol Prog, 38(5), 3280,2022.26. Sabzini M., Pourmadadi M., Yazdian F., Khadiv-Parsi P., Rashedi H., Development of Chitosan/Halloysite/gGraphitic‑Carbon Nitride Nanovehicle for Targeted Delivery of Quercetin to Enhance Its Limitation in Cancer Therapy: An in Vitro Cytotoxicity Against MCF-7 Cells. Int J Biol Macromol,226,159-171,2022.27. Karami MH., Pourmadadi M., Abdouss M., Kalaee MR., Moradi O., Rahdar A., Díez-Pascual AM., Novel Chitosan/γ-Alumina/Carbon Quantum Dot Hydrogel Nanocarrier For Targeted Drug Delivery, Int J Biol Macromol, 251,126280, 2023.28. Karami MH., Abdouss M., Kalaee M.R., MoradiO., A Review of Hydrogels Containing Fibers in Drug Delivery Systems: A Review Study, Iran polymer technology, research and development, In Press,2023.29. Karami MH, Abdouss M, Kalaee M, Moradi O. Chitosan-Based Nanocarriers For The Release Of The Anticancer Drug Curcumin: A Review, Nashrieh Shimi va Mohandesi Shimi Iran, In Press,2023.30. Karami MH.,Abdouss M., Kalaee M.R., MoradiO., Application of Hydrogel Nanocomposites in Biotechnology: A Review Study, Iran polymer technology, research and development, In Press,2023.31. Karami M., Abdouss M., Kalaee M., Moradi O., Investigating the Antibacterial Properties of Chitosan Nanocomposites Containing Metal Nanoparticles For Using in Wound Healings: A Review Study,Basparesh, InPress ,2023.32. Karami M. H., Abdouss M., Kalaee M., MoradiO. The Application of Chitosan-Based Nanocarriers in Improving the Release of The Anticancer Drug Quercetin: A Review Study, Nano World, 19(70), 21-11,2023.33. Zhang Z., He Z., Liang R., Ma Y., Huang W., Jiang R., Fabrication of a Micellar Supramolecular Hydrogel for Ocular Drug Delivery, Biomacromolecules, 17,798–807,2016.34. Satarkar NS., Biswal D., Hilt JZ., Hydrogel Nanocomposites: A Review of Applications As Remote Controlled Biomaterials, Soft Matter, 6,2364 -71,2010.35. Sun X., Liu C., Omer AM., Lu W., Zhang S., Jiang X., PH Sensitive ZnO/Carboxymethyl Cellulose/Chitosan Bionanocomposite Beads for Colon-Specific Release of 5-Fluorouracil, Int J Biol Macromol, 128,468-79,2019.36. Gholamali I., Hosseini SN., Alipour E., Yadollahi M.,Preparation and Characterization of Oxidized Starch/CuO Nanocomposite Hydrogels Applicable in A Drug Delivery System, Starch/Stärke, 71(3-4),1800118,2019.37. Meenach SA., Shapiro JM., Hi l t JZ., Anderson KW., Characterization of PEG-Iron Oxide Hydrogel Nanocomposites for Dual Hyperthermia and Paclitaxel Delivery, J Biomater Sci Polym Ed, 24,1112–26,2013.38. Zhao F., Yao D., Guo R., Deng L., Dong A., Zhang J.,Composites of Polymer Hydrogels and Nanoparticulate Systems for Biomedical and Pharmaceutical Applications, Nanomaterial,5,2054 - 130,2015.39. Sannino A., Demitri C., Madaghiele M., Biodegradable Cellulosebased Hydrogels: Design and Spplications, Material, 2,353- 73,2009.40. Ma J., Li X., Bao Y., Advances in Cellulose-Based Superabsorbent Hydrogels,RSC Adv, 5,59745-57,2015.41. Lombardo D., KiselevMA., CaccamoMT.,Smart nanoparticles for drug delivery application: development of versatile nanocarrier platforms in biotechnology and nanomedicine, J Nanomed, 2019,1-29,2019.42. HeM., Zhao Y., Duan J.,Wang Z., ChenY., Zhang L., Fast Contact of Solid-Liquid Interface Created High Strength Multi-Layered Cellulose Hydrogels with Controllable Size, ACS Appl Mater Interfaces, 6(3),1872–8,2014.43. Qiu X., Hu S., Smart Materials Based on Cellulose: A Review of The Preparations, Properties, and Applications, Material, 6,738- 81,2013.44. Alipour H., Koosha M., Sarraf Shirazi M.J., and Jebali A., Modern Commercial WoundDressings and Introducing New Wound Dressings for Wound Healing: A Review, Basparesh, 6,65-80, 2017.45. Chouhan D., Dey N., Bhardwaj N., and Mandal B.B., Emerging and Innovative Approachesfor Wound Healing and Skin Regeneration: Current Status and Advances, Biomaterials, 216,119267, 2019.46. Yang J.A., Yeom J., Hwang B.W., Hoffman A.S., and Hahn S.K., In Situ Forming InjectableHydrogels for Regenerative Medicine, Prog. Polym. Sci, 39, 1973-1986, 2014.47. Kamoun E.A., Kenawy E.-R.S., and Chen X., A Review on Polymeric Hydrogel Membranesfor Wound Dressing Applications: PVA-Based Hydrogel Dressings, J. Am. Acad. Derm, 8, 217-233, 2017.48. Zahedi P., Rezaeian I., RanaeiSiadat S.O., Jafari S.H., and Supaphol P., A Review on WoundDressings with an Emphasis on Electrospun Nanofibrous Polymeric Bandages, Polym. Adv.Technol, 21, 77-95, 2010.49. Wood R., Williams R., and Hughes L., Foam Elastomer Dressing in the Management of penGranulating Wounds: Experience with 250 Patients, J. Brit. Surg, 64, 554-557, 1977.50. Ruel-Gariepy E. and Leroux J.-C., In Situ Forming Hydrogels-Review of TemperatureSensitive Systems, Europ. J. Pharm. Biopharm, 58, 409-426, 2004.MohsenSadroddiniAminAlamdari12192023657510.66224/irdpt.45132.8.3.65http://irdpt.ir/fa/Article/45132http://irdpt.ir/fa/Article/Download/45132http://irdpt.ir/fa/Article/Download/45132http://irdpt.ir/fa/Article/Download/45132http://irdpt.ir/fa/Article/Download/45132http://irdpt.ir/fa/Article/Download/45132http://irdpt.ir/fa/Article/Download/45132http://irdpt.ir/fa/Article/Download/451321- Yusuf, V.F., N.I. Malek., and S.K. Kailasa., Review on Metal–Organic Framework Classification, Synthetic Approaches, and Influencing Factors: Applications in Energy, Drug Delivery, and Wastewater Treatment, ACS omega, 7(49), 44507-44531, 2022.2- Landaverde-Alvarado, C., A.J. Morris., and S.M. Martin., Characterization of Gas Permeation in the Pores of Zn (II)-Based Metal Organic Framework (MOF)/Polymer Composite Membranes, Separation Science and Technology, 55(14), 2604-2614, 2020.3- Y. Xue., S. Zheng., H. Xue., Metal–Organic Framework Composites and Their Electrochemical Applications, Journal of Materials Chemistry A, 7(13), 7301-7327, 2019.4- Dalal Alezi., Youssef Belmabkhout., Mikhail Suyetin., Prashant M. Bhatt., MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based Soc-MOF for CH4, O2, and CO2 Storage, Journal of the American Chemical Society, 137(41), 13308-13318, 2015.5- Schmidt, B.V., Metal‐Organic Frameworks in Polymer Science: Polymerization Catalysis, Polymerization Environment, and Hybrid Materials, Macromolecular Rapid Communications, 41(1), 1900333, 2020.6- R. Semino., J. Moreton., N. Ramsahye., S. Cohen and G. Maurin., Understanding ohe Origins Of Metal–Organic Framework/Polymer Compatibility, Chem. Sci, 9, 315-324, 2018.7- Kitao, T., and T. Uemura., Polymers in Metal–Organic Frameworks: from Nanostructured Chain Assemblies to New Functional Materials, Chemistry Letters, 49(6), 624-632, 2020.8- T. Kitao., Y. Zhang., S. Kitagawa., B. Wang and T. Uemura., Hybridization of MOFs and Polymers, Chemical Society Reviews, 46(11), 3108-3133, 2017.9- T. Uemura., K. Kitagawa., S. Horike., T. Kawamura., S. Kitagawa., M. Mizuno., Kazunaka Endo., Radical Polymerisation of Styrene in Porous Coordination Polymers, Chemical communications, (48), 5968-5970, 2005.10- T. Uemura., Y. Ono., K. Kitagawa and S. Kitagawa., Radical Polymerization of Vinyl Monomers in Porous Coordination Polymers: Nanochannel Size Effects on Reactivity, Molecular Weight, and Stereostructure, Macromolecules, 41(1), 87-94, 2008.11- T. Uemura., T. Kaseda., Y. Sasaki., M. Inukai., T. Toriyama., A. Takahara., Hiroshi Jinnai., Susumu Kitagawaet., Mixing of Immiscible Polymers Using Nanoporous Coordination Templates, Nature communications, 6(1), 7473, 2015.12- Y. Kobayashi.., Y. Horie, K. Honjo., T. Uemura and S. Kitagawa., he Controlled Synthesis of Polyglucose Iin One-Dimensional Coordination Nanochannels, Chemical Communications, 52(29), 5156-5159, 2016.13- N. Yanai., T. Uemura., M. Ohba., Y. Kadowaki., M. Maesato., M. Takenaka., Shotaro Nishitsuji., Hirokazu Hasegawa., Susumu Kitagawa., Fabrication of Two‐Dimensional Polymer Arrays: Template Synthesis of Polypyrrole Between Redox‐Active Coordination Nanoslits, Angewandte Chemie International Edition, 47(51), 9883-9886, 2008.14- G. Distefano., H. Suzuki., M. Tsujimoto., S. Isoda., S. Bracco., A. Comotti., Piero Sozzani., Takashi Uemura., Susumu Kitagawa., Highly Ordered Alignment of a Vinyl Polymer by Host–Guest Cross-Polymerization, Nature Chemistry, 5(4), 335-341, 2013.15- Z. Zhang., H. T. H. Nguyen., S. A. Miller and S. M. Cohen., Polymofs: a Class of Interconvertible Polymer‐Metal‐Organic‐Framework Hybrid Materials, Angewandte Chemie International Edition, 54(21), 6152-6157, 2015.16- D. Giliopoulos., A. Zamboulis., D. Giannakoudakis., D. Bikiaris and K. Triantafyllidis., Polymer/Metal Organic Framework (MOF) Nanocomposites for Biomedical Applications, Molecules, 25(1), 185, 2020.17- Nagata S., K. Kokado., Metal–Organic Framework Tethering PNIPAM for ON–OFF Controlled Release in Solution, Chemical communications, 51(41), 8614-8617, 2015.18- Y. Zhang., X. Feng., H. Li., Y. Chen., J. Zhao., S. Wang., Photoinduced Postsynthetic Polymerization f Aa Metal–Organic Framework Toward a Flexible Stand‐Alone Membrane, Angewandte Chemie International Edition, 54(14), 4259-4263, 2015.19- K. Xie., Q. Fu., Y. He., J. Kim., S. J. Goh., E. Nam., G. G. Qiao and P. A. Webley., Synthesis of Well Dispersed Polymer Grafted Metal–Organic Framework Nanoparticles, Chemical Communications, 51(85), 15566-15569, 2015.20- B. Le Ouay., C. Watanabe., S. Mochizuki., M. Takayanagi., M. Nagaoka., T. Kitao., Selective Sorting of Polymers with Different Terminal Groups Using Metal-Organic Frameworks, Nature communications, 9(1), 3635, 2018.21- J. Park., Y. S. Chae., D. W. Kang., M. Kang., J. H. Choe., S. Kim., Shaping of a Metal–Organic Framework–Polymer Composite and Its CO2 Adsorption Performances from Humid Indoor Air, ACS Applied Materials & Interfaces, 13(21), 25421-25427, 2021.22- C. Chen., H. Zhu., B.-G. Li and S. Zhu., Fabrication of Metal–Organic Framework/Polymer Composites via a One-Pot Solvent Crystal Template Strategy, Acs Applied Polymer Materials, 3(4), 2038-2044, 2021.23- N. Ding., H. Li., X. Feng., Q. Wang., S. Wang., L. Ma., Partitioning MOF-5 into Confined and Hydrophobic Compartments for Carbon Capture under Humid Conditions, Journal of the American Chemical Society, 138(32), 10100-10103, 2016.24- Bondar, V., B. Freeman, and I. Pinnau., Gas Transport Properties of Poly (Ether‐B‐Amide) Segmented Block Copolymers, Journal of Polymer Science Part B: Polymer Physics, 38(15), 2051-2062, 2000.25- B. Le Ouay., M. Boudot., T. Kitao., T. Yanagida., S. Kitagawa and T. Uemura., Nanostructuration of PEDOT in Porous Coordination Polymers for Tunable Porosity and Conductivity, Journal of the American Chemical Society, 138(32), 10088-10091, 2016.26- Yuwei Shen, Antoine Tissot and Christian Serre., Recent Progress on MOF-based Optical Sensors for VOC Sensing, , Chem. Sci, 13, 13978, 2022.27- S. Basu., M. Maes., A. Cano-Odena., L. Alaerts., D. E. De Vos and I. F. Vankelecom., Solvent Resistant Nanofiltration (SRNF) Membranes Based on Metal-Organic Frameworks, Journal of membrane science, 344(1-2), 190-198, 2009.28- S. Sorribas., P. Gorgojo., C. Téllez., J. Coronas., High Flux Thin Film Nanocomposite Membranes Based on Metal–Organic Frameworks for Organic Solvent Nanofiltration, Journal of the American Chemical Society, 135(40), 15201-15208, 2013.29- A. C. McKinlay., R. E. Morris., P. Horcajada., G. Férey., R. Gref., P. Couvreur., Biomofs: Metal–Organic Frameworks for Biological and Medical Applications, Angewandte Chemie International Edition, 49(36), 6260-6266, 2010.30- Chowdhury, M.A., Metal‐Organic‐Frameworks for Biomedical Applications in Drug Delivery, Aand as MRI Contrast Agents, Journal of Biomedical Materials Research Part A, 105(4), 1184-1194, 2017.