Page 17 - IJB-9-6
P. 17
International Journal of Bioprinting Electrospinning PETG
All authors have read and agreed to the published 13. Hunley MT, Long TE, 2008, Electrospinning functional
version of the manuscript. nanoscale fibers: A perspective for the future. Polym Int,
57(3): 385–389.
References 14. Tang Y, Lan X, Liang C, et al., 2019, Honey loaded alginate/
PVA nanofibrous membrane as potential bioactive wound
1. Mota C, Puppi D, Dinucci D, et al., 2011, Dual-scale dressing. Carbohydr Polym, 219: 113–120.
polymeric constructs as scaffolds for tissue engineering.
Materials, 4(3): 527–542. 15. Stojkovska J, Djurdjevic Z, Jancic I, et al., 2018, Comparative
in vivo evaluation of novel formulations based on alginate
2. Dias JR, Sousa A, Augusto A, et al., 2022, Electrospun and silver nanoparticles for wound treatments. J Biomater
polycaprolactone (PCL) degradation: An in vitro and in vivo Appl, 32(9): 1197–1211.
study. Polymers, 14(16): 3397.
16. Yang X, Wang Y, Qing X, 2019, A flexible capacitive sensor
3. Aslan E, Vyas C, Yupanqui MJ, et al., 2011, Preliminary based on the electrospun PVDF nanofiber membrane with
characterization of a polycaprolactone-SurgihoneyRO carbon nanotubes. Sens Actuators A Phys, 299: 111579.
electrospun mesh for skin tissue engineering. Materials, 17. Hussain Z, Ullah S, Yan J, et al., 2022, Electrospun tannin-
15(1): 89. rich nanofibrous solid-state membrane for wastewater
4. Huang B, Aslan E, Jiang Z, et al., 2020, Engineered dual- environmental monitoring and remediation. Chemosphere,
scale poly (ε-caprolactone) scaffolds using 3D printing and 307: 135810.
rotational electrospinning for bone tissue regeneration. 18. Townsend-Nicholson A, Jayasinghe SN, 2006, Cell
Addit Manuf, 36: 101452. electrospinning: A unique biotechnique for encapsulating
living organisms for generating active biological microthreads/
5. Motamedi AS, Mirzadeh H, Hajiesmaeilbaigi F, et al., 2017, scaffolds. Biomacromolecules, 7(12): 3364–3369.
Effect of electrospinning parameters on morphological
properties of PVDF nanofibrous scaffolds. Progr Biomater, 19. Hong J, Yeo M, Yang GH, et al., 2019, Cell-electrospinning
6: 113–123. and its application for tissue engineering. Int J Mol Sci,
20(24): 6208.
6. Mei Q, Fu R, Ding Y, et al., 2019, Electrospinning of highly
dispersed Ni/CoO carbon nanofiber and its application in 20. Liu F, Vyas C, Poologasundarampillai G, et al., 2018,
glucose electrochemical sensor. J Electroanalyt Chem, 847: Structural evolution of PCL during melt extrusion 3D
113075 %@ 1572–6657. printing. Macromol Mater Eng, 303(2): 1700494.
7. Yarin AL, Koombhongse S, Reneker DH, 2001, Taylor 21. Bartolo P, Malshe A, Ferraris E, et al., 2022, 3D bioprinting:
cone and jetting from liquid droplets in electrospinning of Materials, processes, and applications. CIRP Ann, 71(2):
nanofibers. J Appl Phys, 90(9): 4836–4846. 577–597.
22. Hassan MH, Omar AM, Daskalakis E, et al., 2022, Multi-layer
8. Wu S, Liu J, Qi Y, et al., 2021, Tendon-bioinspired wavy biosensor for pre-symptomatic detection of Puccinia strifformis,
nanofibrous scaffolds provide tunable anisotropy and the causal agent of yellow rust. Biosensors, 12(10): 829.
promote tenogenesis for tendon tissue engineering. Mater
Sci Eng C, 126: 112181. 23. Hassan MH, Omar AM, Daskalakis E, et al., 2020,
Preliminary studies on the suitability of PETG for 4D printing
9. Li Y, Wang J, Qian D, et al., 2021, Electrospun fibrous sponge applications, in 7th International Conference of Materials and
via short fiber for mimicking 3D ECM. J Nanobiotechnol, Manufacturing Engineering (ICMMEN 2020), 6.
19(1): 131.
24. Hassan MH, Omar AM, E. Daskalakis, et al., 2020, The
10. Li M, Qiu W, Wang Q, et al., 2022, Nitric oxide-releasing potential of polyethylene terephthalate glycol as biomaterial
tryptophan-based poly (ester urea) s electrospun composite for bone tissue engineering. Polymers, 12(12): 3045.
nanofiber mats with antibacterial and antibiofilm activities
for infected wound healing. ACS Appl Mater Interfaces, 25. Paralı L, Koç M, Yıldız Z, 2022, 2D/3D direct writing of
14(14): 15911–15926. thermoplastics through electrohydrodynamic printing.
Polym Sci Series A, 64(5): 559–572.
11. Qi Y, Wang C, Wang Q, et al., 2023, A simple, quick, and 26. Luo C, Nangrejo M, Edirisinghe M, 2010, A novel method
cost-effective strategy to fabricate polycaprolactone/silk of selecting solvents for polymer electrospinning. Polymer,
fibroin nanofiber yarns for biotextile-based tissue scaffold 51(7): 1654–1662.
application. Eur Polym J, 186: 111863.
27. Barton AF, 2017, CRC Handbook of Solubility Parameters
12. Vyas C, Ates G, Aslan E, et al., 2020, Three-dimensional and Other Cohesion Parameters, Routledge.
printing and electrospinning dual-scale polycaprolactone
scaffolds with low-density and oriented fibers to promote 28. Heseltine PL, Ahmed J, Edirisinghe M, 2018, Developments
cell alignment. 3D Print Addit Manuf, 7(3): 105–113. in pressurized gyration for the mass production of polymeric
fibers. Macromol Mater Eng, 303(9): 1800218.
Volume 9 Issue 6 (2023) 9 https://doi.org/10.36922/ijb.0024
