irdpt-140502291914050229195721CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagIran Polymer Technology, Research and Developmentirdpt2538-3345313202374RahimDehghanJalalBarzinSeyed Hossein AbtahianBehnamDarabiHamidrezaGhaderi313202351610.66224/irdpt.41600.7.4.5http://irdpt.ir/fa/Article/41600http://irdpt.ir/fa/Article/Download/41600http://irdpt.ir/fa/Article/Download/41600http://irdpt.ir/fa/Article/Download/41600http://irdpt.ir/fa/Article/Download/41600http://irdpt.ir/fa/Article/Download/41600http://irdpt.ir/fa/Article/Download/41600http://irdpt.ir/fa/Article/Download/416001. Vermette P., Griesser J.H., Laroche G., Guidoin R., Biomedical Applications of Polyurethanes, Landes Bioscience, Georgetown,160-168, 2001. 2. Dean IV H., Development of Biopoly Materials for Use in Prosthetic Heart Valve Replacements, MSc Thesis, Colorado state University, Spring 2012. 3. Ansari F., Dehghan R., Role of Polymers Used in Hormone Delivery of Contraceptive Systems for Prevention of Pregnancy, Polymerization, 9, 8-29, 2020. 4. Barzin J., Feng C., Khulbe K.C., Matsuura T., Madaeni S.S., Mirzadeh H, Characterization of Polyethersulfone Hemodialysis Membrane by Ultrafiltration and Atomic Force Microscopy, J. membr. Sci., 237, 77-85, 2004.5. Barzin J., Madaeni S. S., Mirzadeh H., Mehrabzadeh, M. Effect of Polyvinylpyrrolidone on Morphology and Performance of Hemodialysis Membranes Prepared from Polyether Sulfone. Journal of applied polymer science, 92, 6, 3804-3813, 2004.6. Shahrabi S. S., Barzin J., Shokrollahi P., Blood Cell Separation by Novel PET/PVP Blend Electrospun Membranes. Polymer Testing, 66, 94-104, 2018. 7. Shahrabi S. S., Mortaheb H. R., Barzin J., Ehsani M. R., Nanoporous Polyether Sulfone Membrane, Preparation and Characterization: Effect of Porosity and Mean Pore Size on Performance. Journal of Membrane and Separation Technology, 6, 2, 71-84, 2017.8. Bosch T., Thiery J., Gurland H.J., Seidel D., Long-Term Efficiency, Biocompatibility, and Clinical Safety of Combined Simultaneous LDL-Apheresis and Haemodialysis in Patients with Hypercholesterolaemia and End-Stage Renal Failure, Nephrol. Dial. Transplant., 8, 1350-1358, 1993.9. Bantjes A., Clotting Phenomena at the Blood‐Polymer Interface and Development of Blood Compatible Polymeric Surfaces. Polym. Int., 10, 267-274, 1978.10. Gristina A.G., Naylor P.T., Myrvik Q.N., Biomaterial-Centered Infections: Microbial Adhesion Versus Tissue Integration, In Pathogenesis of Wound and Biomaterial-Associated Infections, Springer London, 237, 193-216, 1990.11. Paola F., Messori M., Surface Modification of Polymers: Chemical, Physical, and Biological Routes, In Modification of Polymer Properties, 109-130, 2017.12. Michael W King, Introduction of Blood Coagulation, https://themdicalbiochemistrypage.org/blood-coagulation.php, available in 20 July 2017.13. Franklyn W.D., Blood Compatibility. 1, 89-98, 1987.14. Aebischer P., Schluep M., Déglon N., Joseph J. M., Hirt L., Heyd B., Goddard M., Hammang J.P., Zurn A.D., Kato A.C., Regli F., Intrathecal Delivery of CNTF Using Encapsulated Genetically Modifiedxenogeneic Cells in Amyotrophic Lateral Sclerosis Patients, Nature medicine, 2, 696, 1996.15. Turgeon, M. L., Clinical Hematology: Theory and Procedures. Lippincott Williams & Wilkins, 355-359, 2005.16. Salimi E., Ghaee A., Ismail A. F., Karimi M., Anti-Thrombogenicity and Permeability of Polyethersulfone Hollow Fiber Membrane with Sulfonated Alginate Toward Blood Purification, Inter. J. Biol. Macromol., 116, 364-377, 2018.17. Zhang J., Yan B., He C., Hao Y., Sun S., Zhao W., Zhao C., Urease-Immobilized Magnetic Graphene Oxide as a Safe and Effective Urea Removal Recyclable Nanocatalyst for Blood Purification. Industrial & Engineering Chemistry Research, 59, 19, 8955-8964, 2020.18. Tu M. M., Xu J. J., Qiu Y. R., Surface Hemocompatible Modification of Polysulfone Membrane via Covalently Grafting Acrylic Acid and Sulfonated Hydroxypropyl Chitosan. RSC advances, 9, 11, 6254-6266, 2019.19. Dehghan R., Barzin J., Development of a Polysulfone Membrane with Explicit Characteristics for Separation of Low Density Lipoprotein from Blood Plasma. Polymer Testing, 85, 106438, 2020.20. Dehghan R., Barzin J., Membrane Patterning Through Horizontally Aligned Microchannels Developed by Sulfated Chopped Carbon Fiber for Facile Permeability of Blood Plasma Components in Low-Density Lipoprotein Apheresis. Separation and Purification Technology, 278, 119512, 2021.21. Kamal A. H., Tefferi A., Pruthi R. K., How to Interpret and Pursue an Abnormal Prothrombin Time, Activated Partial Thromboplastin Time and Bleeding Time in Adults. In Mayo Clinic Proceedings, 82, 7, 864-873, 2007.22. Carvalhal F., Cristelo R. R., Resende D. I., Pinto M. M., Sousa E., Correia-da-Silva, M. Antithrombotics from the Sea: Polysaccharides and Beyond. Marine drugs, 17, 3, 170, 2019.23. Zhu L., Song H., Wang J., Xue L., Polysulfone Hemodiafiltration Membranes with Enhanced Anti-Fouling and Hemocompatibility Modified by Poly (Vinyl Pyrrolidone) via in Situ Cross-Linked Polymerization. Materials Science and Engineering: C, 74, 159-166, 2017.24. Huang X. J., Guduru D., Xu Z. K., Vienken J., Groth T., Blood Compatibility and Permeability of Heparin‐Modified Polysulfone as Potential Membrane for Simultaneous Hemodialysis and LDL Removal. Macromolecular bioscience, 11, 1, 131-140, 2011.25. Singh H., Purohit S. D., Bhaskar R., Yadav I., Gupta M. K., Mishra N. C., Development of Decellularization Protocol for Caprine Small Intestine Submucosa as a Biomaterial. Biomaterials and Biosystems, 5, 100035, 2020.26. Venault A., Wu J. R., Chang Y., Aimar P., Fabricating Hemocompatible Bi-Continuous Pegylated PVDF Membranes via Vapor-Induced Phase Inversion. Journal of membrane science, 470, 18-29, 2014.27. Rajaraman R., Rounds D. E., Yen S. P. S., Rembaum A. N. D. A., A Scanning Electron Microscope Study of Cell Adhesion and Spreading In Vitro. Experimental cell research, 88, 2, 327-339, 1974.28. Dehghan R., Barzin J., Low Density Lipoprotein (LDL) Apheresis from Blood Plasma via Anti-Biofouling Tuned Membrane Incorporated with Graphene Oxide-Modified Carrageenan. Journal of Membrane Science, 620, 118878, 2021.29. Nie C., Ma L., Xia Y., He C., Deng J., Wang L., Zhao C., Novel Heparin-Mimicking Polymer Brush Grafted Carbon Nanotube/PES Composite Membranes for Safe and Efficient Blood Purification. Journal of Membrane Science, 475, 455-468, 2015.30. Fukushima K., Inoue Y., Haga Y., Ota T., Honda K., Sato C., Tanaka M., Monoether-Tagged Biodegradable Polycarbonate Preventing Platelet Adhesion and Demonstrating Vascular Cell Adhesion: A Promising Material for Resorbable Vascular Grafts and Stents. Biomacromolecules, 18, 11, 3834-3843, 2017.31. Tsai W. B., Grunkemeier J. M., Horbett T. A., Human Plasma Fibrinogen Adsorption and Platelet Adhesion to Polystyrene. Journal of biomedical materials research, 44, 2, 130-139, 1999.32. Elahi E., Study of Polymer Platelet Adhesion by LDH, Ph.D. thesis, Iran University, Tehran, Iran, 1998.33. Han D. K., Jeong S. Y., Kim Y. H., Min B. G., Cho H. I., Negative Cilia Concept for Thromboresistance: Synergistic Effect of PEO and Sulfonate Groups Grafted onto Polyurethanes. Journal of biomedical materials research, 25, 5, 561-575, 1991.34. Dehghan R., Koosha M., Specification of Polyurethane as Prosthetic Heart Valve, polymerization., 5, 48-60, 2015. 35. Aksoy E.A., Synthesis and Surface Modification Studies of Biomedical Polyurethanes to Improve Long term Biocompatibility, Doctor of Philosophy thesis, Middle east Technical University, 2008.36. Leslie D. C., Waterhouse A., Berthet J. B., Valentin T. M., Watters A. L., Jain A., Super E. H., A Bioinspired Omniphobic Surface Coating on Medical Devices Prevents Thrombosis and Biofouling. Nature biotechnology, 32, 11, 1134, 2014.RasoolMolhsenzadehehsannozad bonab3132023172210.66224/irdpt.41609.7.4.17http://irdpt.ir/fa/Article/41609http://irdpt.ir/fa/Article/Download/41609http://irdpt.ir/fa/Article/Download/41609http://irdpt.ir/fa/Article/Download/41609http://irdpt.ir/fa/Article/Download/41609http://irdpt.ir/fa/Article/Download/41609http://irdpt.ir/fa/Article/Download/41609http://irdpt.ir/fa/Article/Download/416091. Juvinall R.C. and Marshek K.M., Fundamentals of Machine Component design, John Wiley & Sons New York, 2006.2. Davis J.R., Gear Materials, Properties, and Manufacture. ASM International, 2005.3. Kirupasankar S., Gurunathan C., and Gnanamoorthy R., Transmission Efficiency of Polyamide Nanocomposite Spur Gears, Materials & Design, 39, 338-343, 2012.4. Mohsenzadeh R., Soudmand B., and Shelesh-Nezhad K., Failure Analysis of POM Ternary Nanocomposites for Gear Applications: Experimental and Finite Element Study, Engineering Failure Analysis, 140, 106606, 2022.5. Mohsenzadeh R., Soudmand B., and Shelesh-Nezhad K., A Combined Experimental-numerical Approach for Life Analysis and Modeling of Polymer-based Ternary Nanocomposite Gears, Tribology International, 107654, 2022.6. Kim C.H., Durability Improvement Method for Plastic Spur Gears, Tribology International, 39, 11, 1454-1461, 2006.7. Pogačnik A. and Tavčar J., An Accelerated Multilevel Test and Design Procedure for Polymer Gears, Materials & Design, 65, 961-973, 2015.8. Zhang Y., A Physical Investigation of Wear and Thermal Characteristics of 3D Printed Nylon Spur Gears, Tribology International, 141, 105953, 2020.9. Li W., An Investigation on the Wear Behaviour of Dissimilar Polymer Gear Engagements, Wear, 271, 9-10, 2176-2183, 2011.10. Mao K., The Wear and Thermal Mechanical Contact Behaviour of Machine Cut Polymer Gears, Wear, 332, 822-826, 2015.11. Singh P.K. and A.K. Singh, An Investigation on the Thermal and Wear Behavior of Polymer Based Spur Gears, Tribology International, 118, 264-272, 2018.12. Sarita B. and Senthilvelan S., Effects of Lubricant on the Surface Durability of an Injection Molded Polyamide 66 Spur Gear Paired with a Steel Gear, Tribology International, 137, 193-211, 2019.MohsenSadroddini3132023233110.66224/irdpt.41610.7.4.23http://irdpt.ir/fa/Article/41610http://irdpt.ir/fa/Article/Download/41610http://irdpt.ir/fa/Article/Download/41610http://irdpt.ir/fa/Article/Download/41610http://irdpt.ir/fa/Article/Download/41610http://irdpt.ir/fa/Article/Download/41610http://irdpt.ir/fa/Article/Download/41610http://irdpt.ir/fa/Article/Download/416101. Hearle J. W., High-Performance Fibres, Woodhead Publishing Ltd, First, Usa, 2001.2. Guna V., Ilangovan M., Vighnesh H.R., Sreehari, B.R., Abhijith S., Sachin H.E., Mohan C.B., Reddy N., Engineering Sustainable Waste Wool Biocomposites with High Flame Resistance and Noise Insulation for Green Building and Automotive Applications, Journal Of Natural Fibers, 18, 1871-1881, 2021.3. Millington K., Rippon J.A., Wool as a High-Performance Fiber, in Structure and Properties of High-Performance Fibers, Woodhead Publishing Ltd, First, Oxford, 2017.4. Davis M.L., Rippon J.A., the Coloration of Wool and Other Keratin Fibers, First, John Wiley & Sons, Uk, 2013.5. Pekhtasheva E., Neverov A., Kubica S., Zaikov G. E., Biodegradation and Biodeterioration of Some Natural Polymers, Chemistry And Chemical Technology, 6, 263-280, 2012.6. Allafi F., Hossain Md. S., Lalung J., Shaah M., Salehabadi A., Ahmad M. I., Shadi A., Advancements in Applications of Natural Wool Fiber, Journal Of Natural Fibers, 19, 497-512, 2022.7. Szatkowski P., Tadla A., Flis Z., Szatkowska M., Suchorowiec K., Molik E., The Potential Application of Sheep Wool as a Component of Composites. Roczniki Naukowe Polskiego Towarzystwa Zootechnicznego, 17, 1-8, 2021. 8. Korjenic A., Klarić S., Hadžić A., Korjenic S., Sheep Wool as a Construction Material for Energy Efficiency Improvement, Energies, 8, 5765-5781, 2015.9. Leeder J., Rippon J., Changes Induced in the Properties of Wool By Specific Epicuticle Modification, Journal Of The Society Of Dyers And Colourists, 101, 11-16, 1985.10. Shaw T., White M.A., Benisek L., Rushforth M.A., Christoe J.R., Russell I.M., The Chemical Technology of Wool Finishing, in Handbook of Fiber Science and Technology: Chemical Processing of Fibers and Fabrics. First, Routledge. 2018.11. Benisek L., Communication: Improvement of the Natural Flame-Resistance of Wool. Part I: Metal-Complex Applications, Journal Of The Textile Institute, 65 (2) 102-108, 1974. 12. Beheshti M.H., Khavanin A., Safari V. A., Yahya M.N. Bin., Alami A., Khajenasiri F., Talebitooti R., Improving the Sound Absorption of Natural Waste Material-Based Sound Absorbers Using Micro-Perforated Plates, Journal Of Natural Fibers, 19, 1-12, 2021.13. Corscadden K.W., Biggs J.N., Stiles D.K., Sheep's Wool Insulation: a Sustainable Alternative Use for a Renewable Resource?, Resources, Conservation And Recycling, 86, 9-15, 2014.14. Helepciuc C.M., Sheep Wool–A Natural Material Used in Civil Engineering, Buletinul Institutului Politehnic Din Lasi. Sectia Constructii, Arhitectura, 63 (1), 21-30, 2017.15. Zach J., Zach Korjenic A., Petránek V., Hroudová J., Bednar T., Performance Evaluation and Research of Alternative Thermal Insulations Based on Sheep Wool, Energy And Buildings, 49, 246-253, 2012.16. Dénes T.O., Dénes Iştoan, R., Tǎmaş G., Daniela R., Manea D.L., Hegyi A., Popa F,Vasile O., Analysis of Sheep Wool-Based Composites for Building Insulation, Polymers, 14, 2109, 2022.17. Borlea S.I., Tiuc A.E., Nemeş O., Vermeşan H., Vasile O., Innovative Use of Sheep Wool oor Obtaining Materials with Improved Sound-Absorbing Properties, Materials, 13, 694-707, 1-25, 2020.18. Del R.R., Uris A., Alba J., Candelas P., Characterization of Sheep Wool as a Sustainable Material for Acoustic Applications, Materials, 10, 1277, 2017.19. Tămaş G., Daniela R., Dénes T.O., Iştoan R., Tiuc A. E., Manea D. L., Vasile O., A Novel Acoustic Sandwich Panel Based on Sheep Wool, Coatings, 10, 148-162, 2020.amirhasnvand3132023335010.66224/irdpt.41612.7.4.33http://irdpt.ir/fa/Article/41612http://irdpt.ir/fa/Article/Download/41612http://irdpt.ir/fa/Article/Download/41612http://irdpt.ir/fa/Article/Download/41612http://irdpt.ir/fa/Article/Download/41612http://irdpt.ir/fa/Article/Download/41612http://irdpt.ir/fa/Article/Download/41612http://irdpt.ir/fa/Article/Download/41612[1] Egan, P.F.; Bauer, I.; Shea, K.; Ferguson, S.J. Mechanics of Three-Dimensional Printed Lattices for Biomedical Devices. J. Mech. Des, 141, 031703, 2019.[2] Provenzano, D.; Rao, Y.J.; Mitic, K.; Obaid, S.N.; Pierce, D.; Huckenpahler, J.; Berger, J.; Goyal, S.; Loew, M.H. Rapid Prototyping of Reusable 3D-Printed N95 Equivalent Respirators at the George Washington University, 2020030444. 2020.[3] Moniruzzaman, M.; O’Neal, C.; Bhuiyan, A.; Egan, P.F. Design and Mechanical Testing of 3D Printed Hierarchical Lattices Using Biocompatible Stereolithography, 4, 22. 2020. [4] Arabnejad, S.; Johnston, R.B.; Pura, J.A.; Singh, B.; Tanzer, M.; Pasini, D. High-strength porous biomaterials for bone replacement: A strategy to assess the interplay between cell morphology, mechanical properties, bone ingrowth and manufacturing constraints. Acta Biomater, 30, 345–356. 2016.[5] Wang X, Ao Q, Tian X, et al. 3D bioprinting technologies for hard tissue and organ engineering. Materials; 9, 802. 2016.[6] Gross B.C, Erkal J.L, Lockwood S.Y, Chen C, Spenc e D.M. Evaluation of 3D Printing and its Potential Impact on Biotechnology and the Chemical Sciences. ACS Publications; 2014. [7] Xu Y, Wu X, Guo X, et al. The boom in 3D-printed sensor technology. Sensors; 17, 1166. 2017.[8] Alifui-Segbaya, F.; Varma, S.; Lieschke, G.J.; George, R. Biocompatibility of Photopolymers in 3D Printing. 3d Print. Addit. Manuf, 4, 185–191. 2017.[9] Miller, A.T.; Safranski, D.L.; Wood, C.; Guldberg, R.E.; Gall, K. Deformation and fatigue of tough 3D printed elastomer scaffolds processed by fused deposition modeling and continuous liquid interface production. J. Mech. Behav. Biomed. Mater, 75, 1–13. 2017.[10] Nuseir, A.; Hatamleh, M.M.d.; Alnazzawi, A.; Al-Rabab’ah, M.; Kamel, B.; Jaradat, E. Direct 3D printing of flexible nasal prosthesis: Optimized digital workflow from scan to fit. J. Prosthodont, 28, 10–14. 2019.[11] Egan, P.; Wang, X.; Greutert, H.; Shea, K.; Wuertz-Kozak, K.; Ferguson, S. Mechanical and biological characterization of 3D printed lattices. 3d Print. Addit. Manuf, 6, 73–81. 2019.[12] Crump, M.R.; Bidinger, S.L.; Pavinatto, F.J.; Gong, A.T.; Sweet, R.M.; MacKenzie, J.D. Sensorized tissue analogues enabled by a 3D-printed conductive organogel. Npj Flex. Electron, 5, 1–8. 2021.[13] ACFoAM Technologies, ACFoAMTSFo Terminology. Standard Terminology for Additive Manufacturing Technologies. ASTM International; 2012.[14] Liaw C.-Y, Guvendiren M. Current and emerging applications of 3D printing in medicine. Biofabrication; 9:024102. 2017.[15] Ikuta K, Hirowatari K. Real three dimensional micro fabrication using stereo lithography and metal molding, Micro Electro Mechanical Systems. In: MEMS’93, Proceedings an Investigation of Micro Structures, Sensors, Actuators, Machines and Systems IEEE. IEEE1993, 42–47. 1993.[16] Bhatt acharjee N, Urrios A, Kang S, Folch A. The upcoming 3D-printing revolution in microfluidics. Lab a Chip; 16, 1720–1742. 2016.[17] Kumar S. Selective laser sintering: a qualitative and objective approach. JOM (J Occup Med); 55, 43–47. 2003.[18] Kruth J.-P, Mercelis P, Van Vaerenbergh J, Froyen L, Rombouts M. Binding mechanisms in selective laser sintering and selective laser melting. Rapid Prototyping J; 11, 26–36. 2005.[19] Waheed S, Cabot J.M, Macdonald N.P, et al. 3D printed microfluidic devices: enablers and barriers. Lab a Chip; 16, 1993–2013. 2016.[20] Pilipović A, Raos P, Šercer M. Experimental analysis of properties of materials for rapid prototyping. Int J Adv Manuf Technol; 40, 105–115. 2009.[21] Provaggi E, Kalaskar D.M. 3D printing families: laser, powder, nozzle based techniques. 3D Print Med; 21–42, 2017.[22] Murphy S.V, Atala A. 3D bioprinting of tissues and organs. Nat Biotechnol; 32, 773. 2014.[23] Park J, Tari M.J, Hahn H.T. Characterization of the laminated object manufacturing (LOM) process. Rapid Prototyp J; 6, 36–50. 2000. [24] Mueller B, Kochan D. Laminated object manufacturing for rapid tooling and pa ern making in foundry industry. Comput Ind; 39, 47–53. 1999.[25] Horn T.J, Harrysson O.L. Overview of current additive manufacturing technologies and selected applications. Sci Prog; 95, 255–282. 2012.[26] Thompson S.M, Bian L, Shamsaei N, Yadollahi A. A n overview of Direct Laser Deposition for additive manufacturing; part I: transport phenomena, modeling and diagnostics. Additive Manufacturing; 8, 36–62. 2015.[27] Egan, P.F.; Gonella, V.C.; Engensperger, M.; Ferguson, S.J.; Shea, K. Computationally designed lattices with tuned properties for tissue engineering using 3D printing, 12, e0182902. 2017.[28] Revilla-León, M.; Gonzalez-Martín, Ó.; Pérez López, J.; Sánchez-Rubio, J.L.; Özcan, M. Position accuracy of implant analogs on 3D printed polymer versus conventional dental stone casts measured using a coordinate measuring machine. J. Prosthodont, 27, 560–567. 2018.[29] Zuniga, J.; Katsavelis, D.; Peck, J.; Stollberg, J.; Petrykowski, M.; Carson, A.; Fernandez, C. Cyborg beast: A low-cost 3d-printed prosthetic hand for children with upper-limb differences. BMC Res, 8, 10. 2015.[30] Economidou, S.N.; Lamprou, D.A.; Douroumis, D. 3D printing applications for transdermal drug delivery. Int. J. Pharm, 544, 415–424. 2018.[31] Rubio-Perez, I.; Diaz Lantada, A. Surgical Planning of Sacral Nerve Stimulation Procedure in Presence of Sacral Anomalies by Using Personalized Polymeric Prototypes Obtained with Additive Manufacturing Techniques. Polymers, 12, 581. 2020.[32] Erickson, M.M.; Richardson, E.S.; Hernandez, N.M.; Bobbert, D.W., II; Gall, K.; Fearis, P. Helmet Modification to PPE with 3D Printing During the COVID-19 Pandemic at Duke University Medical Center: A Novel Technique. J. Arthroplast, 35, S23–S27. 2020.[33] Hollister, S.J.; Flanagan, C.L.; Zopf, D.A.; Morrison, R.J.; Nasser, H.; Patel, J.J.; Ebramzadeh, E.; Sangiorgio, S.N.; Wheeler, M.B.; Green, G.E. Design control for clinical translation of 3D printed modular scaffolds. Ann. Biomed. Eng, 43, 774–786. 2015.[34] Mai, H.N.; Lee, K.B.; Lee, D.H. Fit of interim crowns fabricated using photopolymer-jetting 3D printing. J. Prosthet. Dent, 118, 208–215. 2017.[35] Swennen, G.R.J.; Pottel, L.; Haers, P.E. Custom-made 3D-printed face masks in case of pandemic crisis situations with a lack of commercially available FFP2/3 masks. Int. J. Oral. Maxillofac. Surg, 49, 673–677. 2020.[36] Roopavath U.K, Kalaskar D.M. Introduction to 3D printing in medicine. 3D Print Med:1– 20 Elsevier, 2017.[37] Ballard D.H, Trace A.P, Ali S, et al. Clinical applications of 3D printing: primer for radiologists. Acad Radiol; 25:52–65. 2018.Mohammad JavadAghajaniMiladGhaniJahan BakhshRaoof3132023516110.66224/irdpt.41613.7.4.51http://irdpt.ir/fa/Article/41613http://irdpt.ir/fa/Article/Download/41613http://irdpt.ir/fa/Article/Download/41613http://irdpt.ir/fa/Article/Download/41613http://irdpt.ir/fa/Article/Download/41613http://irdpt.ir/fa/Article/Download/41613http://irdpt.ir/fa/Article/Download/41613http://irdpt.ir/fa/Article/Download/416131. Xia Z., Zhao Y., & Darling S.B., Covalent Organic Frameworks for Water Treatment, Advanced Materials Interfaces, 8, 2170005, 2021.2. Chen R., Shi J., Ma Y., Lin G., Lang X., & Wang C, Designed Synthesis of a 2D Porphyrin‐Based sp2 Carbon‐conjugated Covalent Organic Framework for Heterogeneous Photocatalysis, Angewandte Chemie International Edition, 58, 6430-6434, 2019.3. Chen Y., Li W., Wang X.H., Gao R.Z., Tang A.N., & Kong D.M, Green Synthesis of Covalent Organic Frameworks Based on Reaction Media, Materials Chemistry Frontiers, 5, 1253-1267, 2019.4. Lohse M.S., & Bein T., Covalent Organic Frameworks: Structures, Synthesis, and Applications, Advanced Functional Materials, 28, 1705553, 2018.5. Lu J., Wang R., Luan J., Li Y., He X., Chen L., & Zhang Y., A Functionalized Magnetic Covalent Organic Framework for Sensitive Determination of Trace Neonicotinoid Residues in Vegetable Samples, Journal of Chromatography A, 1618, 460898, 2020.6. Zhang M., Li J., Zhang C., Wu Z., Yang Y., Li J., Fu F., & Lin Z, In-situ Synthesis of Fluorinated Magnetic Covalent Organic Frameworks for Fluorinated Magnetic Solid-phase Extraction of Ultratrace Perfluorinated Compounds from Milk, Journal of Chromatography A, 1615, 460773, 2020.7. Huang J., Liu X., Zhang W., Liu Z., Zhong H., Shao B., Liang Q., Liu Y., Zhang W., & He Q., Functionalization of Covalent Organic Frameworks by Metal Modification: Construction, Properties and Applications, Chemical Engineering Journal, 404, 127136, 2021.8. Wang J., Yang X., Wei T., Bao J., Zhu Q., & Dai Z, Fe-Porphyrin-based Covalent Organic Framework as a Novel Peroxidase Mimic for a One-pot Glucose Colorimetric Assay, ACS Applied Bio Materials, 1, 382-388, 2018.9. Rahmati Z., Khajavian R., & Mirzaei M, Anisotropy in Metal–organic Framework Thin Films, Inorganic Chemistry Frontiers, 8, 3581-3586, 2021.10. Li W.T., Shi W., Hu Z.J., Yang T., Chen M.L., Zhao B., & Wang J.H, Fabrication of Magnetic Fe3O4@ Metal Organic Framework@ Covalent Organic Framework Composite and its Selective Separation of Trace copper, Applied Surface Science, 530, 147254, 2020.11. Jin E., Li J., Geng K., Jiang Q., Xu H., Xu Q., & Jiang D., Designed Synthesis of Stable Light-emitting Two-dimensional sp2 Carbon-conjugated Covalent Organic Frameworks, Nature communications, 9, 1-10, 2018.12. Zhang C., Yuan H., Lu Z., Li Y., Zhao L., Zhang Z., & Li G., β‐Ketoenamine‐linked Covalent Organic Framework Absorbent for Online Micro‐solid Phase Extraction of Trace Levels Bisphenols in Plastic Samples, Journal of Separation Science, 45, 1493-1501, 2022.13. Hong Z., Dong, Y., Wang R., & Wang G., Evaluation of a Porous Imine-based Covalent Organic Framework for Solid-phase Extraction of Nitroimidazoles, Analytical Methods, 14, 627-634, 2022.14. Wang R., Li C., Li Q., Zhang S., Lv F., & Yan Z, Electrospinning Fabrication of Covalent Organic Framework Composite Nanofibers for Pipette Tip Solid Phase Extraction of Tetracycline Antibiotics in Grass Carp and Duck, Journal of Chromatography A, 1622, 461098, 2020.15. Li W.-T., Hu Z.-J., Meng J., Zhang X., Gao W., Chen M.-L., & Wang J.-H., Zn-based Metal Organic Framework-covalent Organic Framework Composites for Trace Lead Extraction and Fluorescence Detection of TNP, Journal of Hazardous Materials, 411, 125021, 2021.16. Gao Y., Gao M., Chen G., Tian M., Zhai R., Huang X., Xu X., Liu G., & Xu D., Facile Synthesis of Covalent Organic Frameworks Functionalized with Graphene Hydrogel for Effectively Extracting Organophosphorus Pesticides from Vegetables, Food Chemistry, 352, 129187, 2021.17. Hansen F.A., & Pedersen-Bjergaard S., Emerging Extraction Strategies in Analytical Chemistry, Analytical chemistry, 92, 2-15, 2019.18.Wang Z., He M., Chen B., & Hu B, Triazine Covalent Organic Polymer Coated Stir Bar Sorptive Extraction Coupled with High Performance Liquid Chromatography for the Analysis of Trace Phthalate Esters in Mineral Water and Liquor Samples, Journal of Chromatography A, 1660, 462665, 2021. 19. Chen A., Guo H., LuanJ., Li Y., He X., Chen L., & Zhang Y., The Electrospun Polyacrylonitrile/covalent Organic Framework Nanofibers for Efficient Enrichment of Trace Sulfonamides Residues in Food Samples, Journal of Chromatography A, 1668, 462917, 2022.AKBARMIRZAEIshahrzadjavanshirghalzalehMIRZAEI3132023637710.66224/irdpt.41614.7.4.63http://irdpt.ir/fa/Article/41614http://irdpt.ir/fa/Article/Download/41614http://irdpt.ir/fa/Article/Download/41614http://irdpt.ir/fa/Article/Download/41614http://irdpt.ir/fa/Article/Download/41614http://irdpt.ir/fa/Article/Download/41614http://irdpt.ir/fa/Article/Download/41614http://irdpt.ir/fa/Article/Download/416141. Zhang C., Xiang L., Zhang J., Revisiting the Adhesion Mechanism of Mussel-inspired Chemistry, Chemical Science, 13, 1698-170, 2022.2. Kan Y., Danner W., Israelachvili N., Boronate Complex Formation with Dopa Containing Mussel Adhesive Protein Retards PH-Induced Oxidation and Enables Adhesion to Mica, Plos one, 9, 108869. 2014.3. Yu J., et al., Mussel Protein Adhesion Depends on Interprotein Thiol-mediated Redox Modulation. Nat Chem Biol, 7 588-90. 2011.4. Kord Forooshani P., Lee B.P., Recent Approaches in Designing Bioadhesive Materials Inspired by Mussel Adhesive Protein, Journal of Polymer Science Part A: Polymer Chemistry, 55, 9-33. 2017.5. Guo Q., Chen J., Wang J., Recent Progress in Synthesis and Application of Mussel-inspired Adhesives, Nanoscale, 2, 1307-1324. 2020.6. Li Z., Chen Z., Chen H., Polyphenol-based hydrogels: Pyramid Evolution from Crosslinked Structures to Biomedical Applications and the Reverse Design. Bioactive Materials,. 17, 49-70. 2022.7. Yu J., Wei W., Danner E., Israelachvili J., Effects of Interfacial Redox in Mussel Adhesive Protein Films on Mica, Adv Mater, 23, 2362-6. 2011.8. Zhang X., Mussel-inspired Adhesive and Conductive Hydrogel with Tunable Mechanical Properties for Wearable Strain Sensors. Gournal of Colloid and Interface Science, 585, 420-432, 2021.9. Heidarian P., Kouzani A.Z., Kaynak A, Bahrami B., Rational Design of Mussel‐inspired Hydrogels with Dynamic Catecholato− Metal Coordination Bonds, Macromolecular Rapid Communications, 41, 2000439. 2020.10. Gebbie M.A., et al., Tuning Underwater Adhesion with Cation-π Interactions, Nat Chem, 9, 473-479. 2017.11. Fu J., et al., Adsorption of Methylene Blue by a High-efficiency Adsorbent (Polydopamine Microspheres): Kinetics, Isotherm, Thermodynamics and Mechanism Analysis, Chemical Engineering Journal, 259, 53-61. 2015.12. Harrington M.J., Iron-Clad Fibers: a Metal-based Biological Strategy for Hard Flexible Coatings, Science, 328, 216-20. 2010.13. Zeng H., Hwang D.S., Israelachvili J.N., Strong Reversible Fe3+-mediated Bridging Between Dopa-containing Protein Films in Water, Proc Natl Acad Sci U S A., 107, 12850-3. 2010.14. Yan J., Springsteen G., Deeter S., Wang B., The Relationship Among PKA, PH, and Binding Constants in the Interactions Between Boronic Acids and Diols—it is not as Simple as it Appears, Tetrahedron, 60, 11205–11209, 2004.15. Narkar A.R., PH Responsive and Oxidation Resistant Wet Adhesive Based on Reversible Catechol–Boronate Complexation, Chemistry of Materials, 28 5432-5439. 2016.16. Lv R., Bei Z., Huang Y., Mussel‐inspired Flexible, Wearable, and Self‐ adhesive Conductive Hydrogels for Strain Sensors, Macromolecular rapid Communications,. 41, 1900450. 2020.17. Lee H., Scherer N.F., Messersmith P.B., Single-molecule Mechanics of Mussel Adhesion, Proceedings of the National Academy of Sciences, 103, 12999-13003 .2006.18. Han L., Polydopamine Nanoparticles Modulating Stimuli-Responsive Pnipam Hydrogels with Cell/Tissue Adhesiveness, ACS Applied Materials & Interfaces, 8, 29088-29100, 2016.19. Ghavami Nejad A., PH/NIR Light-controlled Multidrug Release via a Mussel-Inspired Nanocomposite Hydrogel for Chemo-photothermal Cancer Therapy, Sci Rep, 6, 33594. 2016.20. Han L., Yan L., Wang M., Transparent, Adhesive, and Conductive Hydrogel for Soft Bioelectronics Based on Light-transmitting Polydopamine-doped Polypyrrole Nanofibrils, Chemistry of Materials, 30, 5561-5572. 2018.21. Rahim M.A., Metal–phenolic Supramolecular Gelation, Angewandte Chemie, 128, 14007-1401.1. 2016.22. Liao M., Wan P., Wen J., Wearable, Healable, and Adhesive Epidermal Sensors Assembled from Mussel-Inspired Conductive Hybrid Hydrogel Framework, Advanced Functional Materials, 27, 1703852. 2017.23. Jing X., Highly Stretchable and Biocompatible Strain Sensors Based on Mussel-Inspired Super-Adhesive Self-healing Hydrogels for Human Motion Monitoring, ACS Applied Materials & Interfaces, 10, 20897-20909. 2018.24. Han L., Lu X., Wang M., A Mussel-inspired Conductive, Self-bdhesive, and Self-Healable Tough Hydrogel as Cell Stimulators and Implantable Bioelectronics, Small, 13, 2017.25. Pan X., Wang Q., He P., Liu K., Mussel-Inspired Nanocomposite Hydrogel-based Electrodes with Reusable and Injectable Properties for Human Electrophysiological Signals Detection, ACS Sustainable Chemistry & Engineering, 7, 7918-7925. 2019.26. Lee B.P., Konst S., Novel Hydrogel Actuator Inspired by Reversible Mussel Adhesive Protein Chemistry, Advanced Materials, 26, 3415-3419. 2014.27. Jiang Z., Strong, Ultrafast, Reprogrammable Hydrogel Actuators with Muscle-Mimetic Aligned Fibrous Structures, Chemistry of Materials, 33, 7818-7828. 2021.28. Zhang C., Vu B., Zhou Y., Mussel-Inspired Hydrogels: from Design Principles to Promising Applications. Chemical Society Reviews, 49, 3605-3637. 2020.29. Han L., Tough, Self-healable and Tissue-adhesive Hydrogel with Tunable Multifunctionality. NPG Asia Materials, 9, e372-e372. 2017.30. Liang Y., Zhao X., Hu T., Mussel-Inspired, Antibacterial, Conductive, Antioxidant, Injectable Composite Hydrogel Wound Dressing to Promote the Regeneration of Infected Skin. Journal of Colloid and Interface Science, 556, 514-528. 2019.31. Xu M., Mussel-inspired Hydrogel with Potent in Vivo Contact-Active Antimicrobial and Wound Healing Promoting Activities, ACS Applied Bio Materials, 2, 3329-3340. 2019.32. Gao H., Sun Y., Zhou J., Rong Xu, Duan H., Mussel-Inspired Synthesis of Polydopamine-functionalized Graphene Hydrogel as Reusable Adsorbents for Water Purification, ACS Applied Materials & Interfaces, 5, 425-432. 2013.33. Zou Y., A Mussel-inspired Polydopamine-filled cellulose Aerogel for Solar-Enabled Water Remediation. ACS Applied Materials & Interfaces, 13, 7617-7624. 2021.34. Bai Z., Mussel-inspired Anti-biofouling and Robust Hybrid Nanocomposite Hydrogel for Uranium Extraction from Seawater. Journal of Hazardous Materials, 381,120984. 2020.35. Cao Y., Zhang ., Mussel-inspired Ag Nanoparticles Anchored Sponge for Oil/water Separation and Contaminants Catalytic Reduction. Separation and Purification Technology, 225, 18-23, 2019.