Structuring of composite hydrogel bioadhesives and its effect on properties and bonding mechanism

Acta Biomaterialia

Volumn 51, Issue , 2017, Pages 125-137

  Pinkas, Oded ^a   Goder, Daniella ^a   Noyvirt, Roni ^a   Peleg, Sivan ^a   Kahlon, Maayan ^a   Zilberman, Meital ^a  

^a TEL AVIV UNIVERSITY   (Israel)

Author keywords

Kaolin; Montmorillonite; Tissue adhesives

Indexed keywords

ADHESIVES; BIOCOMPATIBILITY; CLAY; CROSSLINKING; GELATION; HYDROGELS; KAOLIN; KAOLINITE; PHYSICAL PROPERTIES; SEALANTS; SHEAR FLOW; STRUCTURAL PROPERTIES; SURGERY; TISSUE;

'CURRENT; BIO ADHESIVES; BONDING MECHANISM; BURST STRENGTH; HEMOSTATIC AGENTS; LAYERED SILICATE; MECHANICAL; PROPERTY; SILICATE STRUCTURES; TISSUE ADHESIVES;

ALGINATE;

ALGINIC ACID; CYANAMIDE; GELATIN; HEMOSTATIC AGENT; KAOLIN; MONTMORILLONITE; NANOMATERIAL; SEALANT; TISSUE ADHESIVE; ALUMINUM SILICATE; CLAY; GLUCURONIC ACID; HEXURONIC ACID; HYDROGEL;

ARTICLE; BIOMECHANICS; CHEMICAL BINDING; COMPOSITE MATERIAL; COMPRESSION; CONTROLLED STUDY; CROSS LINKING; CYTOTOXICITY; GELATION; HUMAN; HUMAN CELL; HYDROGEL; PRIORITY JOURNAL; SHEAR STRESS; VISCOSITY; ADHESION; ANIMAL; CELL CULTURE; CELL DEATH; CELL SURVIVAL; CHEMISTRY; DRUG EFFECTS; FISH; PHARMACOLOGY; PIG; TIME FACTOR; X RAY DIFFRACTION;

ADHESIVENESS; ALGINATES; ALUMINUM SILICATES; ANIMALS; CELL DEATH; CELL SURVIVAL; CELLS, CULTURED; FISHES; GELATIN; GLUCURONIC ACID; HEMOSTATICS; HEXURONIC ACIDS; HUMANS; HYDROGEL; KAOLIN; SUS SCROFA; TIME FACTORS; TISSUE ADHESIVES; VISCOSITY; X-RAY DIFFRACTION;

EID: 85010986658     PISSN: 17427061     EISSN: 18787568     Source Type: Journal    
DOI: 10.1016/j.actbio.2017.01.047     Document Type: Article

References (38)

1. [1] Annabi, N., Yue, K., Tamayol, A., Khademhosseini, A., Elastic sealants for surgical applications. Eur. J. Pharm. Biopharm. 95 (2015), 27–39.
2. [2] Mehdizadeh, M., Yang, J., Design strategies and applications of tissue bioadhesives. Macromol. Biosci. 13:3 (2013), 271–288.
3. [3] Ghobril, C., Grinstaff, M., The chemistry and engineering of polymeric hydrogel adhesives for wound closure: a tutorial. Chem. Soc. Rev. 44:7 (2015), 1820–1835.
4. [4] Spotnitz, W.D., Burks, S., Hemostats, sealants, and adhesives III: a new update as well as cost and regulatory considerations for components of the surgical toolbox. Transfusion 52:10 (2012), 2243–2255.
5. [5] Cohen, B., Pinkas, O., Foox, M., Zilberman, M., Gelatin-alginate novel tissue adhesives and their formulation-strength effects. Acta Biomater. 9:11 (2013), 9004–9011.
6. [6] Pinkas, O., Zilberman, M., Effect of hemostatic agents on properties of gelatin–alginate soft tissue adhesives. J. Biomater. Sci. Polym. Ed. 25:6 (2014), 555–573.
7. [7] Kim, Y.-J., Uyama, H., Biocompatible hydrogel formation of gelatin from cold water fish via enzymatic networking. Polym. J. 39:10 (2007), 1040–1046.
8. [8] Chiou, B.-S., Avena-Bustillos, R.J., Bechtel, P.J., Jafri, H., Narayan, R., Imam, S.H., Glenn, G.M., Orts, W.J., Cold water fish gelatin films: effects of cross-linking on thermal, mechanical, barrier, and biodegradation properties. Eur. Polymer J. 44:11 (2008), 3748–3753.
9. [9] Gómez-Guillén, M., Pérez-Mateos, M., Gómez-Estaca, J., López-Caballero, E., Giménez, B., Montero, P., Fish gelatin: a renewable material for developing active biodegradable films. Trends Food Sci. Technol. 20:1 (2009), 3–16.
10. [10] Staroszczyk, H., Pielichowska, J., Sztuka, K., Stangret, J., Kołodziejska, I., Molecular and structural characteristics of cod gelatin films modified with EDC and TGase. Food Chem. 130:2 (2012), 335–343.
11. [11] Jeevithan, E., Qingbo, Z., Bao, B., Wu, W., Biomedical and pharmaceutical application of fish collagen and gelatin: a review. J. Nutr. Therap. 2:4 (2013), 218–227.
12. [12] Pavlidou, S., Papaspyrides, C.D., A review on polymer–layered silicate nanocomposites. Prog. Polym. Sci. 33:12 (2008), 1119–1198.
13. [13] Paul, D.R., Robeson, L.M., Polymer nanotechnology: nanocomposites. Polymer 49:15 (2008), 3187–3204.
14. [14] Kheirabadi, B.S., Mace, J.E., Terrazas, I.B., Fedyk, C.G., Estep, J.S., Dubick, M.A., Blackbourne, L.H., Safety evaluation of new hemostatic agents, smectite granules, and kaolin-coated gauze in a vascular injury wound model in swine. J. Trauma 68:2 (2010), 269–278.
15. [15] Kheirabadi, B.S., Scherer, M.R., Estep, J.S., Dubick, M.A., Holcomb, J.B., Determination of efficacy of new hemostatic dressings in a model of extremity arterial hemorrhage in swine. J. Trauma 67:3 (2009), 450–459 discussion 459-60.
16. [16] Park, H.-M., Li, X., Jin, C.-Z., Park, C.-Y., Cho, W.-J., Ha, C.-S., Preparation and properties of biodegradable thermoplastic starch/clay hybrids. Macromol. Mater. Eng. 287:8 (2002), 553–558.
17. [17] Bae, H.J., Park, H.J., Hong, S.I., Byun, Y.J., Darby, D.O., Kimmel, R.M., Whiteside, W.S., Effect of clay content, homogenization RPM, pH, and ultrasonication on mechanical and barrier properties of fish gelatin/montmorillonite nanocomposite films. LWT-Food Sci. Technol. 42:6 (2009), 1179–1186.
18. [18] Kevadiya, B.D., Joshi, G.V., Patel, H.A., Ingole, P.G., Mody, H.M., Bajaj, H.C., Montmorillonite-alginate nanocomposites as a drug delivery system: Intercalation and in vitro release of vitamin B1 and vitamin B6. J. Biomater. Appl. 25:2 (2010), 161–177.
19. [19] Salcedo, I., Aguzzi, C., Sandri, G., Bonferoni, M.C., Mori, M., Cerezo, P., Sánchez, R., Viseras, C., Caramella, C., In vitro biocompatibility and mucoadhesion of montmorillonite chitosan nanocomposite: a new drug delivery. Appl. Clay Sci. 55 (2012), 131–137.
20. [20] Zheng, J.P., Wang, C.Z., Wang, X.X., Wang, H.Y., Zhuang, H., Yao, K.D., Preparation of biomimetic three-dimensional gelatin/montmorillonite–chitosan scaffold for tissue engineering. React. Funct. Polym. 67:9 (2007), 780–788.
21. [21] Mishra, R.K., Ramasamy, K., Lim, S.M., Ismail, M.F., Majeed, A.B., Antimicrobial and in vitro wound healing properties of novel clay based bionanocomposite films. J. Mater. Sci. Mater. Med. 25:8 (2014), 1925–1939.
22. [22] Ul-Islam, M., Khan, T., Khattak, W.A., Park, J.K., Bacterial cellulose-MMTs nanoreinforced composite films: novel wound dressing material with antibacterial properties. Cellulose 20:2 (2013), 589–596.
23. [23] International Organization for Standardization, ISO 10993, Biological evaluation of medical devices Part 5: Tests for in vitro cytotoxicity, 2009.
24. [24] Mehdizadeh, M., Yang, J., Design strategies and applications of tissue bioadhesives. Macromol. Biosci., 2012.
25. [25] Liu, Y., Kopelman, D., Wu, L.Q., Hijji, K., Attar, I., Preiss-Bloom, O., Payne, G.F., Biomimetic sealant based on gelatin and microbial transglutaminase: an initial in vivo investigation. J. Biomed. Mater. Res. B Appl. Biomater. 91:1 (2009), 5–16.
26. [26] McDermott, M.K., Chen, T., Williams, C.M., Markley, K.M., Payne, G.F., Mechanical properties of biomimetic tissue adhesive based on the microbial transglutaminase-catalyzed crosslinking of gelatin. Biomacromolecules 5:4 (2004), 1270–1279.
27. [27] Sierra, D.H., Eberhardt, A.W., Lemons, J.E., Failure characteristics of multiple-component fibrin-based adhesives. J. Biomed. Mater. Res. 59:1 (2002), 1–11.
28. [28] Lilleheden, L., Mechanical-properties of adhesives in-situ and in bulk. Int. J. Adhes. Adhes. 14:1 (1994), 31–37.
29. [29] Nie, H., He, A., Zheng, J., Xu, S., Li, J., Han, C.C., Effects of chain conformation and entanglement on the electrospinning of pure alginate. Biomacromolecules 9:5 (2008), 1362–1365.
30. [30] Cai, K., Zhang, J., Deng, L., Yang, L., Hu, Y., Chen, C., Xue, L., Wang, L., Physical and biological properties of a novel hydrogel composite based on oxidized alginate, gelatin and tricalcium phosphate for bone tissue engineering. Adv. Eng. Mater. 9:12 (2007), 1082–1088.
31. [31] Lopes, C.M., Felisberti, M.I., Mechanical behaviour and biocompatibility of poly (1-vinyl-2-pyrrolidinone)–gelatin IPN hydrogels. Biomaterials 24:7 (2003), 1279–1284.
32. [32] Li, P., Zheng, J.P., Ma, Y.L., De Yao, K., Gelatin/montmorillonite hybrid nanocomposite. II. Swelling behavior. J. Appl. Polym. Sci. 88:2 (2003), 322–326.
33. [33] Zheng, J.P., Li, P., Ma, Y.L., Yao, K.D., Gelatin/montmorillonite hybrid nanocomposite. I. Preparation and properties. J. Appl. Polym. Sci. 86:5 (2002), 1189–1194.
34. [34] Panzavolta, S., Gioffre, M., Bracci, B., Rubini, K., Bigi, A., Montmorillonite reinforced type A gelatin nanocomposites. J. Appl. Polym. Sci., 131(11), 2014.
35. [35] Miranda-Trevino, J.C., Coles, C.A., Kaolinite properties, structure and influence of metal retention on pH. Appl. Clay Sci. 23:1 (2003), 133–139.
36. [36] Alboofetileh, M., Rezaei, M., Hosseini, H., Abdollahi, M., Effect of montmorillonite clay and biopolymer concentration on the physical and mechanical properties of alginate nanocomposite films. J. Food Eng. 117:1 (2013), 26–33.
37. [37] Martucci, J., Ruseckaite, R., Biodegradable bovine gelatin/Na+-montmorillonite nanocomposite films. Structure, barrier and dynamic mechanical properties. Polym. Plast. Technol. Eng. 49:6 (2010), 581–588.
38. [38] M. Foox, A. Keren, O. Pinkas, E. Cohen, N. Goldsteim, A. Gilhar, M. Zilberman, Y. Ullmann, In vivo efficacy of novel bioadhesives for closure of surgical incisions: Evaluation in a porcine model.