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Correction to Gels 2022, 8(6), 358.
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Correction

Correction: Kovacevic et al. The Effect of Deoxycholic Acid on Chitosan-Enabled Matrices for Tissue Scaffolding and Injectable Nanogels. Gels, 2022, 8, 358

by
Bozica Kovacevic
1,2,
Corina Mihaela Ionescu
1,2,
Melissa Jones
1,2,
Susbin Raj Wagle
1,2,
Michael Lewkowicz
1,2,
Maja Đanić
3,
Momir Mikov
3,
Armin Mooranian
1,2,* and
Hani Al-Salami
1,2,*
1
The Biotechnology and Drug Development Research Laboratory, Curtin Medical School and Curtin Health Innovation Research Institute, Curtin University, Perth, WA 6102, Australia
2
Hearing Therapeutics Department, Ear Science Institute Australia, Queen Elizabeth II Medical Centre, Perth, WA 6009, Australia
3
Department of Pharmacology, Toxicology and Clinical Pharmacology, Faculty of Medicine, University of Novi Sad, 21101 Novi Sad, Serbia
*
Authors to whom correspondence should be addressed.
Gels 2025, 11(12), 1016; https://doi.org/10.3390/gels11121016
Submission received: 28 February 2025 / Accepted: 11 March 2025 / Published: 18 December 2025
Browse Figures
Versions Notes
In Figure 1b [1], the unit “mPas” should be revised to “Pa·s.” In Figure 1d, the Torque unit “mN/M” should be revised to “mN·m.” For Figure 7 (legend and discussion), “basal respiration” should have been “basal oxygen consumption.” The correct Figure 1 and Figure 7 are as follows.
The authors state that the scientific conclusions are unaffected. This correction was approved by the Academic Editor. The original publication has also been updated.

Reference

  1. Kovacevic, B.; Ionescu, C.M.; Jones, M.; Wagle, S.R.; Lewkowicz, M.; Đanić, M.; Mikov, M.; Mooranian, A.; Al-Salami, H. The Effect of Deoxycholic Acid on Chitosan-Enabled Matrices for Tissue Scaffolding and Injectable Nanogels. Gels 2022, 8, 358. [Google Scholar] [CrossRef] [PubMed]
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Figure 1. Rheology results of F1 to F5 formulations presented as values of (a) shear stress, (b) viscosity, (c) surface tension, (d) torque, and (e) zeta potential. p < 0.01 (*) or p < 0.05 (**).
Figure 1. Rheology results of F1 to F5 formulations presented as values of (a) shear stress, (b) viscosity, (c) surface tension, (d) torque, and (e) zeta potential. p < 0.01 (*) or p < 0.05 (**).
Gels 11 01016 g001
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Figure 7. Relationships between bioenergetics in normoxic conditions and viability under normal, low, and high hypoxia. NM OCR, non-mitochondrial-linked OCR; ATP OCR, ATP-production-linked OCR. % maximal respiration—parameter is expressed as a % of maximal respiration, where value of maximal respiration linked OCR is 100%. % basal oxygen consumption—parameter is expressed as a % of basal oxygen consumption, where value of basal oxygen consumption linked OCR is 100%. Figure 7. shows the linear relationship of AML 12 cell viability and (a) NM OCR, (b) NM OCR as % of maximal respiration, (c) NM OCR as % of basal oxygen consumption, (d) ATP OCR, (e) ATP OCR as % of maximal respiration, (f) ATP OCR as % basal oxygen consumption. Figure 7. shows the linear relationship of C2C12 cell viability and (g) NM OCR, (h) NM OCR as % of maximal respiration, (i) NM OCR as % of basal oxygen consumption, (j) ATP OCR, (k) ATP OCR as % of maximal respiration, (l) ATP OCR as % basal oxygen consumption. Figure 7. shows the linear relationship of NIT-1 cell viability and (m) NM OCR, (n) NM OCR as % of maximal respiration, (o) NM OCR as % of basal oxygen consumption, (p) ATP OCR, (r) ATP OCR as % of maximal respiration, (s) ATP OCR as % basal oxygen consumption.
Figure 7. Relationships between bioenergetics in normoxic conditions and viability under normal, low, and high hypoxia. NM OCR, non-mitochondrial-linked OCR; ATP OCR, ATP-production-linked OCR. % maximal respiration—parameter is expressed as a % of maximal respiration, where value of maximal respiration linked OCR is 100%. % basal oxygen consumption—parameter is expressed as a % of basal oxygen consumption, where value of basal oxygen consumption linked OCR is 100%. Figure 7. shows the linear relationship of AML 12 cell viability and (a) NM OCR, (b) NM OCR as % of maximal respiration, (c) NM OCR as % of basal oxygen consumption, (d) ATP OCR, (e) ATP OCR as % of maximal respiration, (f) ATP OCR as % basal oxygen consumption. Figure 7. shows the linear relationship of C2C12 cell viability and (g) NM OCR, (h) NM OCR as % of maximal respiration, (i) NM OCR as % of basal oxygen consumption, (j) ATP OCR, (k) ATP OCR as % of maximal respiration, (l) ATP OCR as % basal oxygen consumption. Figure 7. shows the linear relationship of NIT-1 cell viability and (m) NM OCR, (n) NM OCR as % of maximal respiration, (o) NM OCR as % of basal oxygen consumption, (p) ATP OCR, (r) ATP OCR as % of maximal respiration, (s) ATP OCR as % basal oxygen consumption.
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MDPI and ACS Style

Kovacevic, B.; Ionescu, C.M.; Jones, M.; Wagle, S.R.; Lewkowicz, M.; Đanić, M.; Mikov, M.; Mooranian, A.; Al-Salami, H. Correction: Kovacevic et al. The Effect of Deoxycholic Acid on Chitosan-Enabled Matrices for Tissue Scaffolding and Injectable Nanogels. Gels, 2022, 8, 358. Gels 2025, 11, 1016. https://doi.org/10.3390/gels11121016

AMA Style

Kovacevic B, Ionescu CM, Jones M, Wagle SR, Lewkowicz M, Đanić M, Mikov M, Mooranian A, Al-Salami H. Correction: Kovacevic et al. The Effect of Deoxycholic Acid on Chitosan-Enabled Matrices for Tissue Scaffolding and Injectable Nanogels. Gels, 2022, 8, 358. Gels. 2025; 11(12):1016. https://doi.org/10.3390/gels11121016

Chicago/Turabian Style

Kovacevic, Bozica, Corina Mihaela Ionescu, Melissa Jones, Susbin Raj Wagle, Michael Lewkowicz, Maja Đanić, Momir Mikov, Armin Mooranian, and Hani Al-Salami. 2025. "Correction: Kovacevic et al. The Effect of Deoxycholic Acid on Chitosan-Enabled Matrices for Tissue Scaffolding and Injectable Nanogels. Gels, 2022, 8, 358" Gels 11, no. 12: 1016. https://doi.org/10.3390/gels11121016

APA Style

Kovacevic, B., Ionescu, C. M., Jones, M., Wagle, S. R., Lewkowicz, M., Đanić, M., Mikov, M., Mooranian, A., & Al-Salami, H. (2025). Correction: Kovacevic et al. The Effect of Deoxycholic Acid on Chitosan-Enabled Matrices for Tissue Scaffolding and Injectable Nanogels. Gels, 2022, 8, 358. Gels, 11(12), 1016. https://doi.org/10.3390/gels11121016

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