﻿<?xml version="1.0" encoding="utf-8" ?>
<XML>
  <ISCJOURNAL>
    <YEAR>2021</YEAR>
    <VOL>3</VOL>
    <NO>8</NO>
    <MOSALSAL>8</MOSALSAL>
    <PAGE_NO>12</PAGE_NO>
    <ARTICLES>
      <ARTICLE>
        <LANGUAGE_ID>1</LANGUAGE_ID>
        <TitleF/>
        <TitleE>Preparation of bioactive polymer-based composite by different techniques and application in tissue engineering: A review</TitleE>
        <URL>https://jourcc.com/index.php/jourcc/article/view/jcc337</URL>
        <DOI>10.52547/jcc.3.3.7</DOI>
      	<DOR>20.1001.1.26765837.2021.3.8.7.4</DOR>
        <ABSTRACTS>
          <ABSTRACT>
            <LANGUAGE_ID>1</LANGUAGE_ID>
            <CONTENT>Tissue engineering (TE) employs biological, chemical, and engineering methods
              to regenerate and restore injured or lost living tissues by applying biologically
              activated biomaterials, cells, and molecules. The fast and convenient restoration of
              tissue is a great challenge, emphasizing the need to imitate tissue structure and its
              physicochemical, biological, and mechanical behavior to give back the desired
              functionality of damaged tissue. Depending on the particular tissue, numerous
              requirements have to be fulfilled with the help of material and scaffold design that
              provides a base for cell adhesion and proliferation. As a result, countless
              biodegradable and bioresorbable materials have been extensively examined. Composite
              systems combine the benefits of bioactive ceramics and polymers, which seem to be good
              alternatives for bone tissue engineering. This article intends to introduce bioactive
              polymer, tissue engineering methods, the kinds of biomaterials applied in scaffold
              invention, and the different approaches to producing the bioactive polymer-based
              composites with various structures such as porous, membrane, and 3D structure.
              Biomaterials and invention techniques could crucially influence the consequences of
              the scaffold's design architectures, cell proliferation, and mechanical behavior.
              Moreover, an excellent scaffold assists cell generation and the provision of cell
              nutrients in the human body with their particular material characteristics.</CONTENT>
          </ABSTRACT>
        </ABSTRACTS>
        <PAGES>
          <PAGE>
            <FPAGE>194</FPAGE>
            <TPAGE>205</TPAGE>
          </PAGE>
        </PAGES>
        <AUTHORS>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Mohammad</NameE>
            <MidNameE/>
            <FamilyE>Azad Alam</FamilyE>
            <Organizations>
              <Organization>Universiti Teknologi Petronas</Organization>
            </Organizations>
            <Countries>
              <Country>Malaysia</Country>
            </Countries>
            <EMAILS>
              <Email>info@jourcc.com</Email>
            </EMAILS>
          </AUTHOR>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Mohammad Hamed</NameE>
            <MidNameE/>
            <FamilyE>Asoushe</FamilyE>
            <Organizations>
              <Organization>University of Tehran</Organization>
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>info@jourcc.com</Email>
            </EMAILS>
          </AUTHOR>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Pouran</NameE>
            <MidNameE/>
            <FamilyE>Pourhakkak</FamilyE>
            <Organizations>
              <Organization>Payame Noor University</Organization>
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>info@jourcc.com</Email>
            </EMAILS>
          </AUTHOR>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Lukas</NameE>
            <MidNameE/>
            <FamilyE>Gritsch</FamilyE>
            <Organizations>
              <Organization>Université Clermont Auvergne</Organization>
            </Organizations>
            <Countries>
              <Country>France</Country>
            </Countries>
            <EMAILS>
              <Email>info@jourcc.com</Email>
            </EMAILS>
          </AUTHOR>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Alireza</NameE>
            <MidNameE/>
            <FamilyE>Alipour</FamilyE>
            <Organizations>
              <Organization> Ashkezar Branch, Islamic Azad University (IAU)</Organization>
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>info@jourcc.com</Email>
            </EMAILS>
          </AUTHOR>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Somaye</NameE>
            <MidNameE/>
            <FamilyE>Mohammadi</FamilyE>
            <Organizations>
              <Organization>University of Kashan</Organization>
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>mohamadi_s65@yahoo.com</Email>
            </EMAILS>
          </AUTHOR>
        </AUTHORS>
        <KEYWORDS>
          <KEYWORD>
            <KeyText>Scaffold</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Tissue engineering</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Biodegradable</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Bioresorbable polymer-based composites</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Activated biomaterials</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Bioactive polymer-based composite</KeyText>
          </KEYWORD>
        </KEYWORDS>
        <PDFFileName>Article7.pdf</PDFFileName>
        <REFRENCES>
          <REFRENCE>
            <REF>[1] M.S. Chapekar, Tissue engineering: challenges and opportunities, J.
							Biomed. Mater. Res. An Off. J. Soc. Biomater. Japanese Soc. Biomater.
							Aust. Soc. Biomater. Korean Soc. Biomater. 53 (2000) 617–620. ## [2] S.
							Yin, W. Zhang, Z. Zhang, X. Jiang, Recent Advances in Scaffold Design
							and Material for Vascularized Tissue-Engineered Bone Regeneration, Adv.
							Healthc. Mater. 8 (2019) 1801433. ## [3] L.G. Griffith, G. Naughton,
							Tissue engineering--current challenges and expanding opportunities,
							Science (80-. ). 295 (2002) 1009–1014. ## [4] The Binary Genetic
							Algorithm, in Practical Genetic Algorithms. (2003) 27-50. ## [5] D.
							Nesic, R. Whiteside, M. Brittberg, D. Wendt, I. Martin, P.
							Mainil-Varlet, Cartilage tissue engineering for degenerative joint
							disease, Adv. Drug Deliv. Rev. 58 (2006) 300–322. ## [6] A.A. Vu, D.A.
							Burke, A. Bandyopadhyay, S. Bose, Effects of surface area and topography
							on 3D printed tricalcium phosphate scaffolds for bone grafting
							applications, Addit. Manuf. 39 (2021) 101870. ## [7] J. Sun, Q. Zheng,
							Y. Wu, Y. Liu, X. Guo, W. Wu, Biocompatibility of KLD-12 peptide
							hydrogel as a scaffold in tissue engineering of intervertebral discs in
							rabbits, J. Huazhong Univ. Sci. Technol. [Medical Sci. 30 (2010)
							173–177. ## [8] A. Mishra, Y. Loo, R. Deng, Y.J. Chuah, H.T. Hee, J.Y.
							Ying, C.A.E. Hauser, Ultrasmall natural peptides self-assemble to strong
							temperature-resistant helical fibers in scaffolds suitable for tissue
							engineering, Nano Today. 6 (2011) 232–239. ## [9] B.-S. Kim, D.J.
							Mooney, Development of biocompatible synthetic extracellular matrices
							for tissue engineering, Trends Biotechnol. 16 (1998) 224–230. ## [10] B.
							Guo, P.X. Ma, Synthetic biodegradable functional polymers for tissue
							engineering: a brief review, Sci. China Chem. 57 (2014) 490–500. ## [11]
							A.B. Pratt, F.E. Weber, H.G. Schmoekel, R. Müller, J.A. Hubbell,
							Synthetic extracellular matrices for in situ tissue engineering,
							Biotechnol. Bioeng. 86 (2004) 27–36. ## [12] J.D. Kretlow, A.G. Mikos,
							Mineralization of synthetic polymer scaffolds for bone tissue
							engineering, Tissue Eng. 13 (2007) 927–938. ## [13] R.S. Bhatnagar, J.J.
							Qian, A. Wedrychowska, M. Sadeghi, Y.M. Wu, N. Smith, Design of
							biomimetic habitats for tissue engineering with P-15, a synthetic
							peptide analogue of collagen, Tissue Eng. 5 (1999) 53–65. ## [14] M.P.
							Lutolf, J.A. Hubbell, Synthetic biomaterials as instructive
							extracellular microenvironments for morphogenesis in tissue engineering,
							Nat. Biotechnol. 23 (2005) 47–55. ## [15] K.P. Andriano, Y. Tabata, Y.
							Ikada, J. Heller, In vitro and in vivo comparison of bulk and surface
							hydrolysis in absorbable polymer scaffolds for tissue engineering, J.
							Biomed. Mater. Res. An Off. J. Soc. Biomater. Japanese Soc. Biomater.
							Aust. Soc. Biomater. Korean Soc. Biomater. 48 (1999) 602–612. ## [16] A.
							Kyzioł, K. Kyzioł, Surface functionalization with biopolymers via
							plasma-assisted surface grafting and plasma-induced graft
							polymerization—materials for biomedical applications, in: Biopolym.
							Grafting, Elsevier, (2018) 115–151. ## [17] T. Tariverdian, F. Sefat, M.
							Gelinsky, M. Mozafari, Scaffold for bone tissue engineering, in: Handb.
							Tissue Eng. Scaffolds Vol. One, Elsevier, (2019) 189–209. ## [18] E.I.
							Paşcu, Bioactive and biodegradable scaffolds for hard tissue
							engineering, (2009). ## [19] J.M. Dang, K.W. Leong, Natural polymers for
							gene delivery and tissue engineering, Adv. Drug Deliv. Rev. 58 (2006)
							487–499. ## [20] S.A. Sell, P.S. Wolfe, K. Garg, J.M. McCool, I.A.
							Rodriguez, G.L. Bowlin, The use of natural polymers in tissue
							engineering: a focus on electrospun extracellular matrix analogues,
							Polymers (Basel). 2 (2010) 522–553. ## [21] M. Swetha, K. Sahithi, A.
							Moorthi, N. Srinivasan, K. Ramasamy, N. Selvamurugan, Biocomposites
							containing natural polymers and hydroxyapatite for bone tissue
							engineering, Int. J. Biol. Macromol. 47 (2010) 1–4. ## [22] M. Laurenti,
							V. Cauda, Biodegradable polymer nanocomposites for tissue engineering:
							Synthetic strategies and related applications, in: Mater. Biomed. Eng.,
							Elsevier, (2019) 157–198. ## [23] X. Wang, B. Ding, B. Li, Biomimetic
							electrospun nanofibrous structures for tissue engineering, Mater. Today.
							16 (2013) 229–241. ## [24] R. Sahay, P.S. Kumar, R. Sridhar, J.
							Sundaramurthy, J. Venugopal, S.G. Mhaisalkar, S. Ramakrishna,
							Electrospun composite nanofibers and their multifaceted applications, J.
							Mater. Chem. 22 (2012) 12953–12971. ## [25] A.E. Erickson, J. Sun,
							S.K.L. Levengood, S. Swanson, F.-C. Chang, C.T. Tsao, M. Zhang,
							Chitosan-based composite bilayer scaffold as an in vitro osteochondral
							defect regeneration model, Biomed. Microdevices. 21 (2019) 1–16. ## [26]
							M. Choudhury, S. Mohanty, S. Nayak, Effect of different solvents in
							solvent casting of porous PLA scaffolds—In biomedical and tissue
							engineering applications, J. Biomater. Tissue Eng. 5 (2015) 1–9. ## [27]
							B. Zavan, R. Cortivo, G. Abatangelo, Hydrogels and tissue engineering,
							in: Hydrogels, Springer, (2009) 1–8. ## [28] D.J. Richards, Y. Tan, J.
							Jia, H. Yao, Y. Mei, 3D printing for tissue engineering, Isr. J. Chem.
							53 (2013) 805–814. ## [29] S. Mohammadi, H. Naeimi, A synergetic effect
							of sonication with yolk-shell nanocatalyst for green synthesis of
							spirooxindoles, Green Chem. Lett. Rev. 14 (2021) 344–356. ## [30] H.
							Naeimi, S. Mohammadi, Synthesis of 1H‐Isochromenes, 4H‐Chromenes and
							Orthoaminocarbonitrile Tetrahydronaphthalenes by CaMgFe2O4 Base
							Nanocatalyst, ChemistrySelect. 5 (2020) 2627–2633. ## [31] S. Mohammadi,
							H. Naeimi, A bifunctional Yolk–Shell nanocatalyst with Lewis and organic
							functional base for the synthesis of spirooxindoles, Appl. Catal. A Gen.
							602 (2020) 117720. ## [32] A. Muxika, A. Etxabide, J. Uranga, P.
							Guerrero, K. De La Caba, Chitosan as a bioactive polymer: Processing,
							properties and applications, Int. J. Biol. Macromol. 105 (2017)
							1358–1368. ## [33] A. Michiardi, G. Hélary, P.-C. Nguyen, L.J. Gamble,
							F. Anagnostou, D.G. Castner, V. Migonney, Bioactive polymer grafting
							onto titanium alloy surfaces, Acta Biomater. 6 (2010) 667–675. ## [34]
							D.F. Williams, On the nature of biomaterials, Biomaterials. 30 (2009)
							5897–5909. ## [35] J. Liao, X. Guo, K.J. Grande-Allen, F.K. Kasper, A.G.
							Mikos, Bioactive polymer/extracellular matrix scaffolds fabricated with
							a flow perfusion bioreactor for cartilage tissue engineering,
							Biomaterials. 31 (2010) 8911–8920. ## [36] R. Gentsch, F. Pippig, S.
							Schmidt, P. Cernoch, J. Polleux, H.G. Börner, Single-step
							electrospinning to bioactive polymer nanofibers, Macromolecules. 44
							(2011) 453–461. ## [37] I. Sukmana, Bioactive polymer scaffold for
							fabrication of vascularized engineering tissue, J. Artif. Organs. 15
							(2012) 215–224. ## [38] H. Nargesi khoramabadi, M. Arefian, M. Hojjati,
							I. Tajzad, A. Mokhtarzade, M. Mazhar, A. Jamavari, A review of Polyvinyl
							alcohol/Carboxymethyl cellulose (PVA/CMC) composites for various
							applications, J. Compos. Compd. 2 (2020) 69–76. ## [39] J. Daraei,
							Production and characterization of PCL (Polycaprolactone) coated
							TCP/nanoBG composite scaffolds by sponge foam method for orthopedic
							applications, J. Compos. Compd. 2 (2020) 44–49. ## [40] W. Cao, L.L.
							Hench, Bioactive materials, Ceram. Int. 22 (1996) 493–507. ## [41] W.
							He, R. Benson, Polymeric biomaterials, in: Appl. Plast. Eng. Handb.,
							Elsevier, (2017) 145–164. ## [42] M. Chi, M. Qi, P. Wang, M.D. Weir,
							M.A. Melo, X. Sun, B. Dong, C. Li, J. Wu, L. Wang, Novel bioactive and
							therapeutic dental polymeric materials to inhibit periodontal pathogens
							and biofilms, Int. J. Mol. Sci. 20 (2019) 278. ## [43] A. Abuchenari, K.
							Hardani, S. Abazari, F. Naghdi, M.A. Keleshteri, A. Jamavari, A.M.
							Chahardehi, Clay-reinforced nanocomposites for the slow release of
							chemical fertilizers and water retention, J. Compos. Compd. 2 (2020)
							85–91. ## [44] J.S. Patel, S. V Patel, N.P. Talpada, H.A. Patel,
							Bioactive polymers: Synthesis, release study and antimicrobial
							properties of polymer bound Ampicillin, Die Angew. Makromol. Chemie. 271
							(1999) 24–27. ## [45] C.G. Gebelein, C.E. Carraher, Biotechnology and
							bioactive polymers, Springer, 1994. ## [46] K. Varaprasad, G.M.
							Raghavendra, T. Jayaramudu, M.M. Yallapu, R. Sadiku, A mini review on
							hydrogels classification and recent developments in miscellaneous
							applications, Mater. Sci. Eng. C. 79 (2017) 958–971. ## [47] P. Parida,
							A. Behera, S.C. Mishra, Classification of Biomaterials used in Medicine,
							(2012). ## [48] M.E.S. Hassan, J. Bai, D.-Q. Dou, Biopolymers;
							definition, classification and applications, Egypt. J. Chem. 62 (2019)
							1725–1737. ## [49] K. Zhang, Q. Van Le, Bioactive glass coated zirconia
							for dental implants: a review, J. Compos. Compd. 2 (2020) 10–17. ## [50]
							M.D. Steven, J.H. Hotchkiss, Non-migratory bioactive polymers (NMBP) in
							food packaging, Woodhead Publishing Ltd, Cambridge, UK, 2003. ## [51] Y.
							Ikada, H. Tsuji, Biodegradable polyesters for medical and ecological
							applications, Macromol. Rapid Commun. 21 (2000) 117–132. ## [52] M.
							Kurakula, N.R. Naveen, Prospection of recent chitosan biomedical trends:
							Evidence from patent analysis (2009–2020), Int. J. Biol. Macromol.
							(2020). ## [53] G. Radenković, D. Petković, Metallic biomaterials, in:
							Biomater. Clin. Pract., Springer, (2018) 183–224. ## [54] A.R.
							Boccaccini, J.J. Blaker, Bioactive composite materials for tissue
							engineering scaffolds, Expert Rev. Med. Devices. 2 (2005) 303–317. ##
							[55] M.-H. Thibault, C. Comeau, G. Vienneau, J. Robichaud, D. Brown, R.
							Bruening, L.J. Martin, Y. Djaoued, Assessing the potential of boronic
							acid/chitosan/bioglass composite materials for tissue engineering
							applications, Mater. Sci. Eng. C. 110 (2020) 110674. ## [56] Q. Chen,
							J.A. Roether, A.R. Boccaccini, Tissue engineering scaffolds from
							bioactive glass and composite materials, Top. Tissue Eng. 4 (2008) 1–27.
							## [57] R.A. MacDonald, B.F. Laurenzi, G. Viswanathan, P.M. Ajayan, J.P.
							Stegemann, Collagen–carbon nanotube composite materials as scaffolds in
							tissue engineering, J. Biomed. Mater. Res. Part A An Off. J. Soc.
							Biomater. Japanese Soc. Biomater. Aust. Soc. Biomater. Korean Soc.
							Biomater. 74 (2005) 489–496. ## [58] M.R. Ghahramani, A.A. Garibov, T.N.
							Agayev, M.A. Mohammadi, A novel way to production yttrium glass
							microspheres for medical applications, Glas. Phys. Chem. 40 (2014)
							283–287. ## [59] S.M. Kenny, M. Buggy, Bone cements and fillers: a
							review, J. Mater. Sci. Mater. Med. 14 (2003) 923–938. ## [60] M.
							Kobayashi, T. Nakamura, Y. Okada, A. Fukumoto, T. Furukawa, H. Kato, T.
							Kokubo, T. Kikutani, Bioactive bone cement: Comparison of apatite and
							wollastonite containing glass‐ceramic, hydroxyapatite, and β‐tricalcium
							phosphate fillers on bone‐bonding strength, J. Biomed. Mater. Res. An
							Off. J. Soc. Biomater. Japanese Soc. Biomater. Aust. Soc. Biomater. 42
							(1998) 223–237. ##[61] F. Hajiali, S. Tajbakhsh, A. Shojaei, Fabrication
							and properties of polycaprolactone composites containing calcium
							phosphate-based ceramics and bioactive glasses in bone tissue
							engineering: a review, Polym. Rev. 58 (2018) 164–207. ## [62] A. Hoppe,
							N.S. Güldal, A.R. Boccaccini, A review of the biological response to
							ionic dissolution products from bioactive glasses and glass-ceramics,
							Biomaterials. 32 (2011) 2757–2774. ## [63] T.J. Brunner, W.J. Stark,
							A.R. Boccaccini, Nanoscale bioactive silicate glasses in biomedical
							applications, Pref. XV List Contrib. XIX. (2009). ## [64] L.L. HENCH,
							A.J. SALINAS, Bioactivity of silicate glasses containing phosphate,
							Phosphorus Res. Bull. 6 (1996) 51–58. ## [65] K. Fujikura, N.
							Karpukhina, T. Kasuga, D.S. Brauer, R.G. Hill, R. V Law, Influence of
							strontium substitution on structure and crystallisation of Bioglass®
							45S5, J. Mater. Chem. 22 (2012) 7395–7402. ## [66] K. Rezwan, Q.Z. Chen,
							J.J. Blaker, A.R. Boccaccini, Biodegradable and bioactive porous
							polymer/inorganic composite scaffolds for bone tissue engineering,
							Biomaterials. 27 (2006) 3413–3431. ## [67] W. Florkiewicz, D. Słota, A.
							Placek, K. Pluta, B. Tyliszczak, T.E.L. Douglas, A. Sobczak-Kupiec,
							Synthesis and characterization of polymer-based coatings modified with
							bioactive ceramic and bovine serum albumin, J. Funct. Biomater. 12
							(2021) 21. ## [68] J.K.Y. Lee, N. Chen, S. Peng, L. Li, L. Tian, N.
							Thakor, S. Ramakrishna, Polymer-based composites by electrospinning:
							Preparation and functionalization with nanocarbons, Prog. Polym. Sci. 86
							(2018) 40–84. ## [69] Z. Guo, A.A. Poot, D.W. Grijpma, Advanced
							polymer-based composites and structures for biomedical applications,
							Eur. Polym. J. 149 (2021) 110388. ## [70] N. Cioffi, L. Torsi, N.
							Ditaranto, G. Tantillo, L. Ghibelli, L. Sabbatini, T. Bleve-Zacheo, M.
							D’Alessio, P.G. Zambonin, E. Traversa, Copper nanoparticle/polymer
							composites with antifungal and bacteriostatic properties, Chem. Mater.
							17 (2005) 5255–5262. ## [71] G. Joshi, V. Sharma, R. Saxena, K.S. Yadav,
							Polylactic coglycolic acid (PLGA)-based green materials for drug
							delivery, in: Appl. Adv. Green Mater., Elsevier, (2021) 425–440. ## [72]
							G.S. Mann, L.P. Singh, P. Kumar, S. Singh, C. Prakash, On briefing the
							surface modifications of polylactic acid: A scope for betterment of
							biomedical structures, J. Thermoplast. Compos. Mater. (2019)
							0892705719856052. ## [73] H. Zhou, J.G. Lawrence, S.B. Bhaduri,
							Fabrication aspects of PLA-CaP/PLGA-CaP composites for orthopedic
							applications: a review, Acta Biomater. 8 (2012) 1999–2016. ## [74]
							P.S.P. Poh, M.A. Woodruff, E. García-Gareta, Polymer-based composites
							for musculoskeletal regenerative medicine, in: Biomater. Organ Tissue
							Regen., Elsevier, (2020) 33–82. ## [75] C.R. Holkar, A.J. Jadhav, S.E.
							Karekar, A.B. Pandit, D.V. Pinjari, Recent developments in synthesis of
							nanomaterials utilized in polymer based composites for food packaging
							applications, (n.d.). ## [76] A. Jha, A. Kumar, Biobased technologies
							for the efficient extraction of biopolymers from waste biomass,
							Bioprocess Biosyst. Eng. 42 (2019) 1893–1901. ## [77] Y. Liu, P. Yin, J.
							Chen, B. Cui, C. Zhang, F. Wu, Conducting polymer-based composite
							materials for therapeutic implantations: from advanced drug delivery
							system to minimally invasive electronics, Int. J. Polym. Sci. 2020
							(2020). ## [78] L. Lu, A.G. Mikos, The importance of new processing
							techniques in tissue engineering, Mrs Bull. 21 (1996) 28–32. ## [79] A.
							Prasad, M.R. Sankar, V. Katiyar, State of art on solvent casting
							particulate leaching method for orthopedic scaffoldsfabrication, Mater.
							Today Proc. 4 (2017) 898–907. ## [80] W.L. Murphy, R.G. Dennis, J.L.
							Kileny, D.J. Mooney, Salt fusion: an approach to improve pore
							interconnectivity within tissue engineering scaffolds, Tissue Eng. 8
							(2002) 43–52. ## [81] R. Huang, X. Zhu, H. Tu, A. Wan, The
							crystallization behavior of porous poly (lactic acid) prepared by
							modified solvent casting/particulate leaching technique for potential
							use of tissue engineering scaffold, Mater. Lett. 136 (2014) 126–129. ##
							[82] X. Zhu, T. Zhong, R. Huang, A. Wan, Preparation of hydrophilic poly
							(lactic acid) tissue engineering scaffold via (PLA)-(PLA-b-PEG)-(PEG)
							solution casting and thermal-induced surface structural transformation,
							J. Biomater. Sci. Polym. Ed. 26 (2015) 1286–1296. ## [83] A. Moghanian,
							A. Ghorbanoghli, M. Kazem‐Rostami, A. Pazhouheshgar, E. Salari, M.
							Saghafi Yazdi, T. Alimardani, H. Jahani, F. Sharifian Jazi, M. Tahriri,
							Novel antibacterial Cu/Mg‐substituted 58S‐bioglass: Synthesis,
							characterization and investigation of in vitro bioactivity, Int. J.
							Appl. Glas. Sci. 11 (2020) 685–698. ## [84] P. Abasian, M. Radmansouri,
							M.H. Jouybari, M.V. Ghasemi, A. Mohammadi, M. Irani, F.S. Jazi,
							Incorporation of magnetic NaX zeolite/DOX into the PLA/chitosan
							nanofibers for sustained release of doxorubicin against carcinoma cells
							death in vitro, Int. J. Biol. Macromol. 121 (2019) 398–406. ## [85] S.
							Lee, B. Kim, S.H. Kim, S.W. Kang, Y.H. Kim, Thermally produced
							biodegradable scaffolds for cartilage tissue engineering, Macromol.
							Biosci. 4 (2004) 802–810. ## [86] L. Lu, S.J. Peter, M.D. Lyman, H.-L.
							Lai, S.M. Leite, J.A. Tamada, J.P. Vacanti, R. Langer, A.G. Mikos, In
							vitro degradation of porous poly (L-lactic acid) foams, Biomaterials. 21
							(2000) 1595–1605. ## [87] J.M. Taboas, R.D. Maddox, P.H. Krebsbach, S.J.
							Hollister, Indirect solid free form fabrication of local and global
							porous, biomimetic and composite 3D polymer-ceramic scaffolds,
							Biomaterials. 24 (2003) 181–194. ## [88] R.C. Thomson, M.C. Wake, M.J.
							Yaszemski, A.G. Mikos, Biodegradable polymer scaffolds to regenerate
							organs, Biopolym. Ii. (1995) 245–274. ## [89] N. Thadavirul, P.
							Pavasant, P. Supaphol, Development of polycaprolactone porous scaffolds
							by combining solvent casting, particulate leaching, and polymer leaching
							techniques for bone tissue engineering, J. Biomed. Mater. Res. Part A.
							102 (2014) 3379–3392. ## [90] R.C. Thomson, A.K. Shung, M.J. Yaszemski,
							A.G. Mikos, Polymer scaffold processing, Princ. Tissue Eng. 2 (2000)
							251–262. ## [91] K.H. Bouhadir, D.J. Mooney, In vitro and In vivo Models
							for the Reconstruction of Intercellular Signaling a, (1998). ## [92]
							S.L. Ishaug-Riley, L.E. Okun, G. Prado, M.A. Applegate, A. Ratcliffe,
							Human articular chondrocyte adhesion and proliferation on synthetic
							biodegradable polymer films, Biomaterials. 20 (1999) 2245–2256. ## [93]
							M. Singh, B. Sandhu, A. Scurto, C. Berkland, M.S. Detamore,
							Microsphere-based scaffolds for cartilage tissue engineering: Using
							subcritical CO2 as a sintering agent, Acta Biomater. 6 (2010) 137–143.
							## [94] B. Duan, M. Wang, Encapsulation and release of biomolecules from
							Ca–P/PHBV nanocomposite microspheres and three-dimensional scaffolds
							fabricated by selective laser sintering, Polym. Degrad. Stab. 95 (2010)
							1655–1664. ## [95] L.S. Fard, N.S. Peighambardoust, H.W. Jang, A.
							Dehghan, N.N.K. Saligheh, M. Iranpour, M.I. Rajabi, The rechargeable
							aluminum-ion battery with different composite cathodes: A review, J.
							Compos. Compd. 2 (2020) 138–146. ## [96] A.A. Chaudhari, K. Vig, D.R.
							Baganizi, R. Sahu, S. Dixit, V. Dennis, S.R. Singh, S.R. Pillai, Future
							prospects for scaffolding methods and biomaterials in skin tissue
							engineering: a review, Int. J. Mol. Sci. 17 (2016) 1974. ## [97] T.
							Weigel, G. Schinkel, A. Lendlein, Design and preparation of polymeric
							scaffolds for tissue engineering, Expert Rev. Med. Devices. 3 (2006)
							835–851. ## [98] L.S. Farda, N.S. Peighambardoustb, H.W. Jangc, A.
							Dehghand, N.N.K. Salighehe, M. Iranpourf, M.I. Rajabig, Journal of
							Composites and Compounds, (2020). ## [99] K.M.Z. Hossain, U. Patel, I.
							Ahmed, Development of microspheres for biomedical applications: a
							review, Prog. Biomater. 4 (2015) 1–19.
							https://doi.org/10.1007/s40204-014-0033-8. ## [100] I.J. Roh, S.
							Ramaswamy, W.B. Krantz, A.R. Greenberg, Poly (ethylene
							chlorotrifluoroethylene) membrane formation via thermally induced phase
							separation (TIPS), J. Memb. Sci. 362 (2010) 211–220. ## [101] J.T. Jung,
							J.F. Kim, H.H. Wang, E. Di Nicolo, E. Drioli, Y.M. Lee, Understanding
							the non-solvent induced phase separation (NIPS) effect during the
							fabrication of microporous PVDF membranes via thermally induced phase
							separation (TIPS), J. Memb. Sci. 514 (2016) 250–263. ## [102] H.
							Matsuyama, S. Berghmans, D.R. Lloyd, Formation of anisotropic membranes
							via thermally induced phase separation, Polymer (Guildf). 40 (1999)
							2289–2301. ## [103] Y.S. Nam, T.G. Park, Porous biodegradable polymeric
							scaffolds prepared by thermally induced phase separation, J. Biomed.
							Mater. Res. An Off. J. Soc. Biomater. Japanese Soc. Biomater. Aust. Soc.
							Biomater. Korean Soc. Biomater. 47 (1999) 8–17. ## [104] H. Matsuyama,
							M. Yuasa, Y. Kitamura, M. Teramoto, D.R. Lloyd, Structure control of
							anisotropic and asymmetric polypropylene membrane prepared by thermally
							induced phase separation, J. Memb. Sci. 179 (2000) 91–100. ## [105] D.R.
							Lloyd, S.S. Kim, K.E. Kinzer, Microporous membrane formation via
							thermally-induced phase separation. II. Liquid—liquid phase separation,
							J. Memb. Sci. 64 (1991) 1–11. ## [106] R. Zeinali, L.J. Del Valle, J.
							Torras, J. Puiggalí, Recent progress on biodegradable tissue engineering
							scaffolds prepared by thermally-induced phase separation (Tips), Int. J.
							Mol. Sci. 22 (2021) 3504. ## [107] Y.S. Nam, T.G. Park, Biodegradable
							polymeric microcellular foams by modified thermally induced phase
							separation method, Biomaterials. 20 (1999) 1783–1790. ## [108] G. Chen,
							Y. Lin, X. Wang, Formation of microporous membrane of isotactic
							polypropylene in dibutyl phthalate‐soybean oil via thermally induced
							phase separation, J. Appl. Polym. Sci. 105 (2007) 2000–2007. ## [109]
							S.S. Kim, D.R. Lloyd, Thermodynamics of polymer/diluent systems for
							thermally induced phase separation: 2. Solid-liquid phase separation
							systems, Polymer (Guildf). 33 (1992) 1036–1046. ## [110] I.L. TUTOR,
							PLLA-BASED SCAFFOLDS FOR OSTEOCHONDRAL TISSUE REGENERATION VIA THERMALLY
							INDUCED PHASE SEPARATION TECHNIQUE, (n.d.). ## [111] X. Li, X. Lu,
							Morphology of polyvinylidene fluoride and its blend in thermally induced
							phase separation process, J. Appl. Polym. Sci. 101 (2006) 2944–2952. ##
							[112] Z. Cui, N.T. Hassankiadeh, S.Y. Lee, J.M. Lee, K.T. Woo, A.
							Sanguineti, V. Arcella, Y.M. Lee, E. Drioli, Poly (vinylidene fluoride)
							membrane preparation with an environmental diluent via thermally induced
							phase separation, J. Memb. Sci. 444 (2013) 223–236. ## [113] G.A.
							Mannella, G. Conoscenti, F.C. Pavia, V. La Carrubba, V. Brucato,
							Preparation of polymeric foams with a pore size gradient via Thermally
							Induced Phase Separation (TIPS), Mater. Lett. 160 (2015) 31–33. ## [114]
							F.C. Pavia, V. La Carrubba, S. Piccarolo, V.M.B. Brucato, Polymeric
							scaffolds prepared via thermally induced phase separation: tuning of
							structure and morphology, J. Biomed. Mater. Res. Part A An Off. J. Soc.
							Biomater. Japanese Soc. Biomater. Aust. Soc. Biomater. Korean Soc.
							Biomater. 86 (2008) 459–466. ## [115] R. Akbarzadeh, A. Yousefi, Effects
							of processing parameters in thermally induced phase separation technique
							on porous architecture of scaffolds for bone tissue engineering, J.
							Biomed. Mater. Res. Part B Appl. Biomater. 102 (2014) 1304–1315. ##
							[116] J.T. Jung, H.H. Wang, J.F. Kim, J. Lee, J.S. Kim, E. Drioli, Y.M.
							Lee, Tailoring nonsolvent-thermally induced phase separation (N-TIPS)
							effect using triple spinneret to fabricate high performance PVDF hollow
							fiber membranes, J. Memb. Sci. 559 (2018) 117–126. ## [117] D.R. Lloyd,
							K.E. Kinzer, H.S. Tseng, Microporous membrane formation via thermally
							induced phase separation. I. Solid-liquid phase separation, J. Memb.
							Sci. 52 (1990) 239–261. ## [118] D. Li, W.B. Krantz, A.R. Greenberg,
							R.L. Sani, Membrane formation via thermally induced phase separation
							(TIPS): Model development and validation, J. Memb. Sci. 279 (2006)
							50–60. ## [119] H. Khalilpour, P. Shafiee, A. Darbandi, M. Yusuf, S.
							Mahmoudi, Z. Moazzami Goudarzi, S. Mirzamohammadi, Application of
							Polyoxometalate-based composites for sensor systems: A review, J.
							Compos. Compd. 3 (2021) 129–139. https://doi.org/10.52547/jcc.3.2.6. ##
							[120] S. Ramaswamy, A.R. Greenberg, W.B. Krantz, Fabrication of poly
							(ECTFE) membranes via thermally induced phase separation, J. Memb. Sci.
							210 (2002) 175–180. ##[121] F. Sharifianjazi, A.H. Pakseresht, M.S. Asl,
							A. Esmaeilkhanian, H.W. Jang, M. Shokouhimehr, Hydrox-yapatite
							consolidated by zirconia: applications for dental implant, J. Compos.
							Compd. 2 (2020) 26–34. ## [122] M.Z. Moghadam, S. Hassanajili, F.
							Esmaeilzadeh, M. Ayatollahi, M. Ahmadi, Formation of porous HPCL/LPCL/HA
							scaffolds with supercritical CO2 gas foaming method, J. Mech. Behav.
							Biomed. Mater. 69 (2017) 115–127. ## [123] L.J. White, V. Hutter, H.
							Tai, S.M. Howdle, K.M. Shakesheff, The effect of pro-cessing variables
							on morphological and mechanical properties of supercritical CO2 foamed
							scaffolds for tis-sue engineering, Acta Biomater. 8 (2012) 61–71. ##
							[124] A. Salerno, S. Zeppetelli, E. Di Maio, S. Iannace, P.A. Netti,
							Design of bimodal PCL and PCL‐HA nanocomposite scaffolds by two step
							depressurization during solid‐state supercritical CO2 foaming, Macromol.
							Rapid Commun. 32 (2011) 1150–1156. ## [125] C.-X. Chen, Q.-Q. Liu, X.
							Xin, Y.-X. Guan, S.-J. Yao, Pore formation of poly (ε-caprolactone)
							scaffolds with melt-ing point reduction in supercritical CO2 foaming, J.
							Supercrit. Fluids. 117 (2016) 279–288. ## [126] A. Saler-no, S.
							Zeppetelli, E. Di Maio, S. Iannace, P.A. Netti, Novel 3D porous
							multi-phase composite scaffolds based on PCL, thermoplastic zein and ha
							prepared via supercritical CO2 foaming for bone regeneration, Compos.
							Sci. Technol. 70 (2010) 1838–1846. ## [127] M. Alizadeh, F.
							Sharifianjazi, E. Haghshenasjazi, M. Aghakhani, L. Rajabi, Production of
							nanosized boron oxide powder by high-energy ball milling, Synth. React.
							Inorganic, Met. Nano-Metal Chem. 45 (2015) 11–14. ## [128] F.S. Jazi, N.
							Parvin, M. Tahriri, M. Alizadeh, S. Abedini, M. Alizadeh, The
							relationship between the synthesis and morphology of SnO2-Ag2O
							nanocomposite, Synth. React. Inorganic, Met. Nano-Metal Chem. 44 (2014)
							759–764. ## [129] R. Jiang, T. Liu, Z. Xu, C.B. Park, L. Zhao, Improving
							the continuous microcellular extrusion foaming ability with
							supercritical CO2 of thermo-plastic polyether ester elastomer through
							in-situ fibrillation of polytetrafluoroethylene, Polymers (Basel). 11
							(2019) 1983. ## [130] K. Wang, Y. Pang, F. Wu, W. Zhai, W. Zheng, Cell
							nucleation in dominating formation of bimodal cell structure in
							polypropylene/polystyrene blend foams prepared via continuous extrusion
							with supercritical CO2, J. Supercrit. Fluids. 110 (2016) 65–74. ## [131]
							Y. Jia, S. Bai, C.B. Park, Q. Wang, Effect of boric acid on the foaming
							properties and cell structure of poly (vinyl alcohol) foam prepared by
							supercriti-cal-CO2 thermoplastic extrusion foaming, Ind. Eng. Chem. Res.
							56 (2017) 6655–6663. ## [132] L.M. Matu-ana, C.A. Diaz, Study of cell
							nucleation in microcellular poly (lactic acid) foamed with supercritical
							CO2 through a continuous-extrusion process, Ind. Eng. Chem. Res. 49
							(2010) 2186–2193. ## [133] H.-Y. Mi, X. Jing, Y. Liu, L. Li, H. Li,
							X.-F. Peng, H. Zhou, Highly durable superhydrophobic polymer foams
							fabricated by extrusion and supercritical CO2 foaming for selective oil
							absorption, ACS Appl. Mater. Interfaces. 11 (2019) 7479–7487. ## [134]
							N. Le Moigne, M. Sauceau, M. Benyakhlef, R. Jemai, J.-C. Bénézet, E.
							Rodier, J.-M. Lopez-Cuesta, J. Fages, Foaming of poly
							(3-hydroxybutyrate-co-3-hydroxyvalerate)/organo-clays nano-biocomposites
							by a continuous supercritical CO2 assisted extrusion process, Eur.
							Polym. J. 61 (2014) 157–171. ## [135] M. Chauvet, M. Sauceau, J. Fages,
							Extrusion assisted by supercritical CO2: A review on its ap-plication to
							biopolymers, J. Supercrit. Fluids. 120 (2017) 408–420. ## [136] R.
							Kapoor, A. Jash, S.S.H. Rizvi, Shelf-life extension of Paneer by a
							sequential supercritical-CO2-based process, LWT. 135 (2021) 110060. ##
							[137] A. Nouri, B. Faraji Dizaji, N. Kianinejad, A. Jafari Rad, S.
							Rahimi, M. Irani, F. Sharifian Jazi, Simulta-neous linear release of
							folic acid and doxorubicin from ethyl cellulose/chitosan/g-C3N4/MoS2
							core-shell nano-fibers and its anticancer properties, J. Biomed. Mater.
							Res. Part A. 109 (2021) 903–914. ## [138] S. Khorshidi, A. Solouk, H.
							Mirzadeh, S. Mazinani, J.M. Lagaron, S. Sharifi, S. Ramakrishna, A
							review of key challenges of electrospun scaffolds for tissue-engineering
							applications, J. Tissue Eng. Regen. Med. 10 (2016) 715–738. ## [139]
							A.P. Kishan, E.M. Cosgriff-Hernandez, Recent advancements in
							electrospinning design for tissue engi-neering applications: A review,
							J. Biomed. Mater. Res. Part A. 105 (2017) 2892–2905. ## [140] D.R.
							Nisbet, J.S. Forsythe, W. Shen, D.I. Finkelstein, M.K. Horne, A review
							of the cellular response on electrospun nano-fibers for tissue
							engineering, J. Biomater. Appl. 24 (2009) 7–29. ## [141] H. Pan, L. Li,
							L. Hu, X. Cui, Contin-uous aligned polymer fibers produced by a modified
							electrospinning method, Polymer (Guildf). 47 (2006) 4901–4904. ## [142]
							H. Li, X. Chen, W. Lu, J. Wang, Y. Xu, Y. Guo, Application of
							Electrospinning in Anti-bacterial Field, Nanomaterials. 11 (2021) 1822.
							## [143] X. Wang, K. Zhang, M. Zhu, H. Yu, Z. Zhou, Y. Chen, B.S. Hsiao,
							Continuous polymer nanofiber yarns prepared by self-bundling
							electrospinning method, Polymer (Guildf). 49 (2008) 2755–2761. ## [144]
							Y.-H. Wu, D.-G. Yu, H.-P. Li, X.-Y. Wu, X.-Y. Li, Medicat-ed structural
							PVP/PEG composites fabricated using coaxial electrospinning, E-Polymers.
							17 (2017) 39–44. ## [145] G. Sargazi, D. Afzali, A. Mostafavi, H.
							Kazemian, A novel composite derived from a metal organic framework
							immobilized within electrospun nanofibrous polymers: An efficient
							methane adsorbent, Appl. Or-ganomet. Chem. 34 (2020) e5448. ## [146]
							W.E. Teo, S. Ramakrishna, A review on electrospinning design and
							nanofibre assemblies, Nanotechnology. 17 (2006) R89. ## [147] H.Y. Li,
							M.M. Bubakir, T. Xia, X.F. Zhong, Y.M. Ding, W.M. Yang, Mass production
							of ultra-fine fibre by melt electrospinning method using umbellate
							spinneret, Mater. Res. Innov. 18 (2014) S4-921. ## [148] F.S. Jazi, N.
							Parvin, M. Rabiei, M. Tahriri, Z.M. Shabestari, A.R. Azadmehr, Effect of
							the synthesis route on the grain size and morphology of ZnO/Ag
							nanocomposite, J. Ceram. Process. Res. 13 (2012) 523–526. ## [149] M.J.
							Mochane, T.S. Motsoeneng, E.R. Sadiku, T.C. Mokhena, J.S. Sefadi,
							Morphology and properties of electrospun PCL and its composites for
							medical applications: A mini review, Appl. Sci. 9 (2019) 2205. ## [150]
							F.A. Sheikh, H.W. Ju, J.M. Lee, B.M. Moon, H.J. Park, O.J. Lee, J.-H.
							Kim, D.-K. Kim, C.H. Park, 3D electrospun silk fibroin nanofibers for
							fabri-cation of artificial skin, Nanomedicine Nanotechnology, Biol. Med.
							11 (2015) 681–691. ## [151] A. Shokati, A.N. Moghadasi, M. Nikbakht,
							M.A. Sahraian, S.A. Mousavi, J. Ai, A focus on allogeneic mesenchymal
							stro-mal cells as a versatile therapeutic tool for treating multiple
							sclerosis, Stem Cell Res. Ther. 12 (2021) 1–13. ## [152] Y. Piao, H.
							You, T. Xu, H.-P. Bei, I.Z. Piwko, Y.Y. Kwan, X. Zhao, Biomedical
							applications of gela-tin methacryloyl hydrogels, Eng. Regen. 2 (2021)
							47–56. ## [153] X. Sun, Q. Lang, H. Zhang, L. Cheng, Y. Zhang, G. Pan,
							X. Zhao, H. Yang, Y. Zhang, H.A. Santos, Electrospun photocrosslinkable
							hydrogel fibrous scaffolds for rapid in vivo vascularized skin flap
							regeneration, Adv. Funct. Mater. 27 (2017) 1604617. ## [154] G.Y. Xu,
							L.N. Chen, Z.Y. Xin, Y.X. Liu, T.C. Li, L.P. An, G.X. Yuan, Y. Sheng,
							P.G. Du, H.Y. Li, Re-view on clinical application of deproteinized calf
							blood extractive, in: Appl. Mech. Mater., Trans Tech Publ, (2014)
							1617–1621. ## [155] Y. Zamani, H. Ghazanfari, G. Erabi, A. Moghanian, B.
							Fakić, S.M. Hosseini, B.P. Mahammod, A review of additive manufacturing
							of Mg-based alloys and composite implants, J. Compos. Compd. 3 (2021)
							71–83. ## [156] K. Gunawardana, Introduction of Advanced Manufacturing
							Technology: a literature review, Sabaragamuwa Univ. J. 6 (2006) 116–134.
							## [157] J. Savolainen, M. Collan, How additive manufacturing technology
							changes business models?–review of literature, Addit. Manuf. 32 (2020)
							101070. ## [158] F.T.S. Chan, M.H. Chan, H. Lau, R.W.L. Ip, Investment
							appraisal techniques for advanced manufac-turing technology (AMT): a
							literature review, Integr. Manuf. Syst. (2001). ## [159] M. Vaezi, H.
							Seitz, S. Yang, A review on 3D micro-additive manufacturing
							technologies, Int. J. Adv. Manuf. Technol. 67 (2013) 1721–1754. ## [160]
							C.-H. Chen, J.M.-J. Liu, C.-K. Chua, S.-M. Chou, V.B.-H. Shyu, J.-P.
							Chen, Cartilage tissue engineering with silk fibroin scaffolds
							fabricated by indirect additive manufacturing technology, Mate-rials
							(Basel). 7 (2014) 2104–2119. ## [161] H. Canziani, S. Chiera, T.
							Schuffenhauer, S. Kopp, F. Metzger, A. Bück, M. Schmidt, N. Vogel,
							Bottom-Up Design of Composite Supraparticles for Powder-Based Additive
							Manufacturing, Small. 16 (2020) 2002076. ## [162] S. Dolnicar, A.
							Chapple, A.J. “ANGIOSTRONGYLUS-V.I.N.D.I.N.W.. V.R. 120. 1. (1987):
							424-424. ## [163] L. Zhao, X. Wang, H. Xiong, K. Zhou, D. Zhang,
							Op-timized preceramic polymer for 3D structured ceramics via fused
							deposition modeling, J. Eur. Ceram. Soc. 41 (2021) 5066–5074. ## [164]
							K. Ryan, Additive Manufacturing of Graphene Nanoplatelets and Hexagonal
							Bo-ron Nitride Composites Via Stereolithography, (2020). ## [165] S.
							Jang, S. Park, C. Bae, Development of ce-ramic additive manufacturing:
							process and materials technology, Biomed. Eng. Lett. (2020) 1–11. ##
							[166] L.J. Tan, W. Zhu, K. Zhou, Recent progress on polymer materials
							for additive manufacturing, Adv. Funct. Ma-ter. 30 (2020) 2003062. ##
							[167] M. Warschauer, Researching technology in TESOL: Determinist,
							instrumen-tal, and critical approaches, TESOL Q. 32 (1998) 757–761. ##
							[168] J. Zhou, J. Lin, X. Huang, Y. Zhou, Y. Chen, J. Xia, H. Wang, Y.
							Xie, H. Yu, J. Lei, A library of atomically thin metal chalcogenides,
							Nature. 556 (2018) 355–359. ## [169] T. Jungst, W. Smolan, K. Schacht,
							T. Scheibel, J. Groll, Strategies and molecular design criteria for 3D
							printable hydrogels, Chem. Rev. 116 (2016) 1496–1539. ## [170] U.
							Jammalamadaka, K. Tappa, Recent advances in biomaterials for 3D printing
							and tissue engineering, J. Funct. Biomater. 9 (2018) 22. ## [171] A.
							Bruyas, F. Lou, A.M. Stahl, M. Gardner, W. Maloney, S. Goodman, Y.P.
							Yang, Sys-tematic characterization of 3D-printed PCL/β-TCP scaffolds for
							biomedical devices and bone tissue engineer-ing: Influence of
							composition and porosity, J. Mater. Res. 33 (2018) 1948–1959. ## [172]
							M. Vaezi, S. Chian-rabutra, B. Mellor, S. Yang, Multiple material
							additive manufacturing–Part 1: a review: this review paper co-vers a
							decade of research on multiple material additive manufacturing
							technologies which can produce com-plex geometry parts with different
							materials, Virtual Phys. Prototyp. 8 (2013) 19–50. ## [173] H. Li, B.-J.
							Li, Z.-J. Shi, Challenge and progress: palladium-catalyzed sp 3 C–H
							activation, Catal. Sci. Technol. 1 (2011) 191–206. ## [174]
							Functionalized NiFe2O4/mesopore silica anchored to guanidine
							nanocomposite as a catalyst for synthesis of 4H-chromenes under
							ultrasonic irradiation, J. Compos. Compd. 3 (2021).
							https://doi.org/10.52547/jcc.3.2.1. ## [175] S. Nasibi, K. Alimohammadi,
							L. Bazli, S. Eskandarinezhad, A. Mohammadi, N. Sheysi, TZNT alloy for
							surgical implant applications: A systematic review, J. Compos. Compd. 2
							(2020) 62–68. ## [176] S.H. Park, T.G. Kim, H.C. Kim, D.-Y. Yang, T.G.
							Park, Development of du-al scale scaffolds via direct polymer melt
							deposition and electrospinning for applications in tissue regenera-tion,
							Acta Biomater. 4 (2008) 1198–1207. ## [177] S. Naghieh, M.R.K. Ravari,
							M. Badrossamay, E. Fo-roozmehr, M. Kadkhodaei, Numerical investigation
							of the mechanical properties of the additive manufactured bone scaffolds
							fabricated by FDM: the effect of layer penetration and post-heating, J.
							Mech. Behav. Biomed. Mater. 59 (2016) 241–250. ## [178] M.L.
							Muerza-Cascante, D. Haylock, D.W. Hutmacher, P.D. Dalton, Melt
							electrospinning and its technologization in tissue engineering, Tissue
							Eng. Part B Rev. 21 (2015) 187–202. ## [179] T.G. Kim, D.S. Lee, T.G.
							Park, Controlled protein release from electrospun biodegradable fiber
							mesh composed of poly (ɛ-caprolactone) and poly (ethylene oxide), Int.
							J. Pharm. 338 (2007) 276–283. ## [180] O. Mazalevska, M.H. Struszczyk,
							I. Krucinska, Design of vascular prostheses by melt
							electrospinning—structural characterizations, J. Appl. Polym. Sci. 129
							(2013) 779–792. ## [181] V. Balouchi, F.S. Jazi, A. Saidi, Devel-oping
							(W, Ti) C-(Ni, Co) nanocomposite by SHS method, J. Ceram. Process. Res.
							16 (2015) 605–608. ## [182] A. Deraine, M.T. Rebelo Calejo, R. Agniel,
							M. Kellomäki, E. Pauthe, M. Boissière, J. Massera, Poly-mer-Based
							Honeycomb Films on Bioactive Glass: Toward a Biphasic Material for Bone
							Tissue Engineering Applications, ACS Appl. Mater. Interfaces. (2021). ##
							[183] M. Wang, Composite scaffolds for bone tissue engineering, Am. J.
							Biochem. Biotechnol. (2006). ## [184] I.O. Oladele, T.F. Omotosho, A.A.
							Adediran, Pol-ymer-based composites: an indispensable material for
							present and future applications, Int. J. Polym. Sci. 2020 (2020). ##
							[185] K.T. Arul, E. Manikandan, R. Ladchumananandasivam, Polymer-based
							calcium phosphate scaffolds for tissue engineering applications, in:
							Nanoarchitectonics Biomed., Elsevier, (2019) 585–618. ## [186] L. Bazli,
							M. Yusuf, A. Farahani, M. Kiamarzi, Z. Seyedhosseini, M. Nezhadmansari,
							M. Aliasghari, M. Iranpoor, Application of composite conducting polymers
							for improving the corrosion behavior of various sub-strates: A Review,
							J. Compos. Compd. 2 (2020) 228–240. ## [187] S. V Dorozhkin, Calcium
							orthophosphate-based bioceramics, Materials (Basel). 6 (2013) 3840–3942.
							## [188] W. Zakrzewski, M. Dobrzynski, Z. Rybak, M. Szymonowicz, R.J.
							Wiglusz, Selected nanomaterials’ application enhanced with the use of
							stem cells in acceleration of alveolar bone regeneration during
							augmentation process, Nanomaterials. 10 (2020) 1216. ## [189] Y. Liu, J.
							Lim, S.-H. Teoh, Development of clinically relevant scaffolds for
							vascularised bone tissue engineering, Biotechnol. Adv. 31 (2013)
							688–705. ## [190] P. Bartolo, J.-P. Kruth, J. Silva, G. Levy, A. Malshe,
							K. Rajurkar, M. Mitsuishi, J. Ciurana, M. Leu, Biomedical production of
							implants by additive elec-tro-chemical and physical processes, CIRP Ann.
							61 (2012) 635–655. ## [191] Y.-M. Huang, Y.-C. Lin, C.-Y. Chen, Y.-Y.
							Hsieh, C.-K. Liaw, S.-W. Huang, Y.-H. Tsuang, C.-H. Chen, F.-H. Lin,
							Thermosensitive chitosan–gelatin–glycerol phosphate hydrogels as
							collagenase carrier for tendon–bone healing in a rabbit model, Poly-mers
							(Basel). 12 (2020) 436.</REF>
          </REFRENCE>
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