EDP Sciences logo
Submit your paper
Search
Menu
All issues Volume 10 (2025) Renew. Energy Environ. Sustain., 10 (2025) 3 References
Open Access
Issue
Renew. Energy Environ. Sustain.
Volume 10, 2025
Article Number 3
Number of page(s) 15
DOI https://doi.org/10.1051/rees/2025003
Published online 23 December 2025
  1. A. Sorushanova, L.M. Delgado, Z. Wu, N. Shologu, A. Kshirsagar, R. Raghunath, A.M. Mullen, Y. Bayon, A. Pandit, M. Raghunath, D.I. Zeugolis, The collagen suprafamily: from biosynthesis to advanced biomaterial development, Adv. Mater. 31, 1801651 (2019) [Google Scholar]
  2. P. Yadav, H. Yadav, V.G. Shah, G. Shah, G. Dhaka, Biomedical biopolymers, their origin and evolution in biomedical sciences: a systematic review, J. Clin. Diagn. Res.: JCDR. 9, ZE21 (2015). S.H. Mok, G. Bi, J. Folkes, I. Pashby, Deposition of Ti − 6Al − 4V using a high power diode laser and wire, Part I: investigation on the process characteristics, 2015. https://doi.org/10.1016/j.surfcoat.2008.02.008 [Google Scholar]
  3. M. Meyer, Processing of collagen based biomaterials and the resulting materials properties, Biomed. Eng. online. 18, 24 (2019) [Google Scholar]
  4. S. Pradhan, A.K. Brooks, V.K. Yadavalli, Nature-derived materials for the fabrication of functional biodevices, Mater. Today Bio. 7, 100065 (2020) [Google Scholar]
  5. T. Biswal, Biopolymers for tissue engineering applications: a review, Mater. Today: Proc. 41, 397–402 (2021) [Google Scholar]
  6. C. Dong, Y. LV, Application of collagen scaffold in tissue engineering: recent advances and new perspectives, Polymers. 8, 42 (2016) [Google Scholar]
  7. Z. Morsada, M.M. Hossain, M.T. Islam, M.A. Mobin, S. Saha, Recent progress in biodegradable and bioresorbable materials: from passive implants to active electronics, Appl. Mater. Today. 25, 101257 (2021) [Google Scholar]
  8. S.S. Shaji, K. Kamalasanan, S. Harika, A. Tiwari, B. Raj, Natural biopolymer for 3D printing, J. Polymer Sci. Eng. 6, 3016 (2023) [Google Scholar]
  9. C. Ferroni, G. Varchi, Keratin-based nanoparticles as drug delivery carriers, Appl. Sci. 11, 9417 (2021) [Google Scholar]
  10. J. McLellan, S.G. Thornhill, S. Shelton, M. Kumar, Keratin-based biofilms, hydrogels, and biofibers. InKeratin as a protein biopolymer: extraction from waste biomass and applications (Springer International Publishing, Cham, 2018), pp. 187–200 [Google Scholar]
  11. A. Oryan, A. Kamali, A. Moshiri, H. Baharvand, H. Daemi, Chemical crosslinking of biopolymeric scaffolds: current knowledge and future directions of crosslinked engineered bone scaffolds, Int. J. Biol. Macromol. 107, 678–688 (2018) [Google Scholar]
  12. H. Kırmızıbekmez, D. Demir, IriDoid glycosides and phenolic compounds from the flowers of vitex agnus‐castus, Helvetica Chimica Acta. 99, 518–522 (2016) [Google Scholar]
  13. M. Schröpfer, M. Meyer, Research article investigations towards the binding mechanisms of vegetable tanning agents to collagen, Res. J. Phytochem. 10, 58–66 (2016) [Google Scholar]
  14. A.P. Antunes, G. Attenburrow, A.D. Covington, J. Ding, Utilisation of oleuropein as a crosslinking agent in collagenic films, J. Leather Sci. 2, 1 (2008) [Google Scholar]
  15. S.N. Park, J.C. Park, H.O. Kim, M.J. Song, H. Suh, Characterization of porous collagen/hyaluronic acid scaffold modified by 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide cross-linking, Biomaterials. 23, 1205–1212 (2002) [Google Scholar]
  16. P. Hartrianti, L.T. Nguyen, J. Johanes, S.M. Chou, P. Zhu, N.S. Tan, M.B. Tang, K.W. Ng, Fabrication and characterization of a novel crosslinked human keratin‐alginate sponge, J. Tissue Eng. Regen. Med. 11, 2590–2602 (2017) [Google Scholar]
  17. N. Davidenko, C.F. Schuster, D.V. Bax, N. Raynal, R.W. Farndale, S.M. Best, R.E. Cameron, Control of crosslinking for tailoring collagen-based scaffolds stability and mechanics, Acta Biomater. 25, 131–142 (2015) [Google Scholar]
  18. B.B. Mandal, J.K. Mann, S.C. Kundu, Silk fibroin/gelatin multilayered films as a model system for controlled drug release, Eur. J. Pharm. Sci. 37, 160–171 (2009) [Google Scholar]
  19. S. Sadeghi, J. Nourmohammadi, A. Ghaee, N. Soleimani, Carboxymethyl cellulose-human hair keratin hydrogel with controlled clindamycin release as antibacterial wound dressing, Int. J. Biol. Macromol. 147, 1239–1247 (2020) [Google Scholar]
  20. A. Joorabloo, M.T. Khorasani, H. Adeli, Z. Mansoori-Moghadam, A. Moghaddam, Fabrication of heparinized nano ZnO/poly (vinylalcohol)/carboxymethyl cellulose bionanocomposite hydrogels using artificial neural network for wound dressing application, J. Ind. Eng. Chem. 70, 253–263 (2019) [Google Scholar]
  21. W. Shao, J. Wu, S. Wang, M. Huang, X. Liu, R. Zhang, Construction of silver sulfadiazine loaded chitosan composite sponges as potential wound dressings, Carbohydr. Polym. 157, 1963–1970 (2017) [Google Scholar]
  22. Q.L. Loh, C. Choong, Three-dimensional scaffolds for tissue engineering applications: role of porosity and pore size, Tissue Eng. Part B: Rev. 19, 3 (2013) [Google Scholar]
  23. K. Belbachir, R. Noreen, G. Gouspillou, C. Petibois, Collagen types analysis and differentiation by FTIR spectroscopy, Anal. Bioanal. Chem. 395, 829–837 (2009) [Google Scholar]
  24. A. Martínez Cortizas, O. López-Costas, Linking structural and compositional changes in archaeological human bone collagen: an FTIR-ATR approach, Sci. Rep. 10, 17888 (2020) [Google Scholar]
  25. T. Riaz, R. Zeeshan, F. Zarif, K. Ilyas, N. Muhammad, S.Z. Safi, A. Rahim, S.A. Rizvi, I.U. Rehman, FTIR analysis of natural and synthetic collagen, Appl. Spectrosc. Rev. 53, 703–746 (2018) [CrossRef] [Google Scholar]
  26. B. de Campos Vidal, M.L. Mello, Collagen type I amide I band infrared spectroscopy, Micron. 42, 283–289 (2011) [Google Scholar]
  27. C. Stani, L. Vaccari, E. Mitri, G. Birarda, FTIR investigation of the secondary structure of type I collagen: new insight into the amide III band, Spectrochim. Acta Part A: Mol. Biomol. Spectrosc. 229, 118006 (2020) [Google Scholar]
  28. T.W. Sun, W.L. Yu, C. Qi, F. Chen, Y.J. Zhu, Y.H. He, Multifunctional simvastatin-loaded porous hydroxyapatite microspheres/collagen composite scaffold for sustained drug release, angiogenesis and osteogenesis, J. Control. Release. 259, e130 (2017) [Google Scholar]
  29. H.S. Canbay, M. Doğantürk, Compatibility studies of sildenafil with different excipients by using TGA, DSC, XRD and FTIR, Celal Bayar Univ. J. Sci. 15, 401–407 (2019) [Google Scholar]
  30. P. Knauth, H. Hou, E. Bloch, E. Sgreccia, M.L. Di Vona, Thermogravimetric analysis of SPEEK membranes: thermal stability, degree of sulfonation and cross-linking reaction, J. Anal. Appl. Pyrol. 92, 361–365 (2011) [Google Scholar]
  31. P. Budrugeac, L. Miu, The suitability of DSC method for damage assessment and certification of historical leathers and parchments, J. Cult. Herit. 9, 146–153 (2008) [Google Scholar]
  32. Y. Zhang, Z. Chen, X. Liu, J. Shi, H. Chen, Y. Gong, SEM, FTIR and DSC investigation of collagen hydrolysate treated degraded leather, J. Cult. Herit. 48, 205–210 (2021) [Google Scholar]
  33. H. Capella-Monsonís, J.Q. Coentro, V. Graceffa, Z. Wu, D.I. Zeugolis, An experimental toolbox for characterization of mammalian collagen type I in biological specimens, Nat. Protoc. 13, 507–529 (2018) [Google Scholar]
  34. N. Prasad, N. Thombare, S.C. Sharma, S. Kumar, Gum Arabic–a versatile natural gum: a review on production, processing, properties and applications, Ind. Crops Prod. 187, 115304 (2022) [Google Scholar]
  35. D.A. Safta, C. Bogdan, S. Iurian, M.L. Moldovan, Optimization of film-dressings containing herbal extracts for wound care—a quality by design approach, Gels. 11, 322 (2025) [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.