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International Journal of Bioprinting 3D printability and biochemical analysis of orange peel waste

19. Mantihal S, Prakash S, Bhandari B, 2019, Texture‐modified Citrus unshiu peel using subcritical water. J Food Eng,
3D printed dark chocolate: Sensory evaluation and 110:472–477.
consumer perception study. J Texture Stud, 50(5):386–399.
34. Leo CH, Foo SY, Tan JCW, et al., 2022, Green extraction of orange
20. Liu Z, Bhandari B, Guo C, et al., 2021, 3D printing of peel waste reduces TNFα-induced vascular inflammation and
shiitake mushroom incorporated with gums as dysphagia endothelial dysfunction. Antioxidants, 11:1768.
diet. Foods, 10:2189.
35. Venkatesan T, Choi Y-W, Kim Y-K, 2019, Effect of an
21. Karyappa R, Hashimoto M, 2019, Chocolate-based ink extraction solvent on the antioxidant quality of Pinus
three-dimensional printing (Ci3DP). Sci Rep, 9:14178. densiflora needle extract. J Pharm Anal, 9(3):193–200.
22. Lee CP, Karyappa R, Hashimoto M, 2020, 3D printing of 36. Lee JM, Yeong WY, 2020, Engineering macroscale cell
milk-based product. RSC Adv, 10:29821–29828. alignment through coordinated toolpath design using
support-assisted 3D bioprinting. J R Soc Interface,
23. Keerthana K, Anukiruthika T, Moses JA, et al., 2020,
Development of fiber-enriched 3D printed snacks from 17(168):20200294.
alternative foods: A study on button mushroom. J Food Eng, 37. Leo CH, Lee CP, Foo SY, et al., 2022, 3D printed nutritious
287:110116. snacks from orange peel waste. Mater Today Proc, In press.
24. Tan JJY, Lee CP, Hashimoto M, 2020, Preheating of gelatin https://doi.org/10.1016/j.matpr.2022.08.484
improves its printability with transglutaminase in direct ink 38. Ong ES, Low J, Tan JCW, et al., 2022, Valorization of avocado
writing 3d printing. Int J Bioprint, 6:296. seeds with antioxidant capacity using pressurized hot water
25. Wang L, Zhang M, Bhandari B, et al., 2018, Investigation on extraction. Sci Rep, 12:1–11.
fish surimi gel as promising food material for 3D printing. J 39. Saini RK, Ranjit A, Sharma K, et al., 2022, Bioactive
Food Eng, 220:101–108. compounds of citrus fruits: A review of composition and
26. Lee CP, Takahashi M, Arai S, et al., 2021, 3D printing of health benefits of carotenoids, flavonoids, limonoids, and
okara ink: The effect of particle size on the printability. ACS terpenes. Antioxidants, 11:239.
Food Sci Technol, 1:2053–2061. 40. Leo CH, Hart JL, Woodman OL, 2011, 3’,4’-dihydroxyflavonol
27. Muthurajan M, Veeramani A, Rahul T, et al., 2021, reduces superoxide and improves nitric oxide function in
Valorization of food industry waste streams using 3D food diabetic rat mesenteric arteries. PLoS One, 6:e20813.
printing: A study on noodles prepared from potato peel https://doi.org/10.1371/journal.pone.0020813
waste. Food Bioproc Technol, 14(10):1817–1834.
41. Ng HH, Leo CH, O’Sullivan K, et al., 2017, 1,4-Anhydro-
28. Zhang Y, Lee AY, Pojchanun K, et al., 2022, Systematic 4-seleno-d-talitol (SeTal) protects endothelial function in
engineering approach for optimisation of multi-component the mouse aorta by scavenging superoxide radicals under
alternative protein-fortified 3D printing food Ink. Food conditions of acute oxidative stress. Biochem Pharmacol,
Hydrocolloids, 131:107803. 128:34–45.
29. Jagadiswaran B, Alagarasan V, Palanivelu P, et al., 2021, 42. Leo CH, Jelinic M, Ng HH, et al., 2016, Serelaxin: A novel
Valorization of food industry waste and by-products using therapeutic for vascular diseases. Trends Pharmacol Sci,
3D printing: A study on the development of value-added 37:498–507.
functional cookies. Future Foods, 4:100036. 43. Leo CH Woodman OL, 2015, Flavonols in the prevention
30. Maldonado-Rosas R, Tejada-Ortigoza V, Cuan-Urquizo E, of diabetes-induced vascular dysfunction. J Cardiovasc
et al., 2022, Evaluation of rheology and printability of 3D Pharmacol, 65:532–544.
printing nutritious food with complex formulations. Addit 44. Marshall SA, Qin C, Jelinic M, et al., 2020, The novel small-
Manuf, 58:103030. molecule annexin-A1 mimetic, compound 17b, elicits
31. Ong ES, Oh CLY, Tan JCW, et al., 2021, Pressurized hot water vasoprotective actions in streptozotocin-induced diabetic
extraction of okra seeds reveals antioxidant, antidiabetic mice. Int J Mol Sci, 21:pii: E1384.
and vasoprotective activities. Plants, 10:1645. https://doi.org/10.3390/ijms21041384
https://doi.org/10.3390/plants10081645 45. Kahlberg N, Qin C, Anthonisz J, et al., 2016, Adverse vascular
remodelling is more sensitive than endothelial dysfunction to
32. Ong ES, Pek CJN, Tan JCW, et al., 2020, Antioxidant and
cytoprotective effect of quinoa (Chenopodium quinoa hyperglycaemia in diabetic rat mesenteric arteries. Pharmacol
Willd.) with pressurized hot water extraction (PHWE). Res, 111:325–335.
Antioxidants, 9:1110. 46. Li JC, Velagic A, Qin C, et al., 2021, Diabetes attenuates the
contribution of endogenous nitric oxide but not nitroxyl to
https://doi.org/10.3390/antiox9111110
endothelium dependent relaxation of rat carotid arteries.
33. Cheigh C-I, Chung E-Y, Chung M-S, 2012, Enhanced Front Pharmacol, 11:585740.
extraction of flavanones hesperidin and narirutin from
https://doi.org/10.3389/fphar.2020.585740

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