Early effect of graphene oxide-carboxymethyl chitosan hydrogel loaded with interleukin 4 and bone morphogenetic protein 2 on bone immunity and repair_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

ZOU Min ^1,2 , SUN Jiachen ¹ ,  XIANG Zhou ¹

1. Department of Orthopedics, West China Hospital, Sichuan University, Chengdu Sichuan, 610041, P.R.China;
2. Department of Orthopedics, Chengdu First People’s Hospital, Chengdu Sichuan, 610016, P.R.China;

Corresponding author：

XIANG Zhou, Email: xiangzhou15@hotmail.com

Keywords：

Graphene oxide; carboxymethyl chitosan; interleukin 4; bone morphogenetic protein 2; macrophages; bone marrow mesenchymal stem cells; rat

DOI：

10.7507/1002-1892.201911068

Video：

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Objective To investigate the effect of graphene oxide (GO)-carboxymethyl chitosan (CMC) hydrogel loaded with interleukin 4 (IL-4) and bone morphogenetic protein 2 (BMP-2) on macrophages M2 type differentiation and osteogenic differentiation of bone marrow mesenchymal stem cells (BMSCs).Methods GO solution was mixed with CMC, then the phosphate buffered saline (PBS), IL-4, BMP-2, or IL-4+BMP-2 were added to prepare different GO-CMC hydrogel scaffolds with or without different cytokines under crosslinking agents. The characteristics of pure GO-CMC hydrogel were characterized by gross observation, scanning electron microscope (SEM), and Fourier transform infrared spectroscopy (FTIR), and the CMC hydrogel was used as control. The sustained release of GO-CMC hydrogels with different cytokines was also tested. Macrophages were isolated and cultured from female Sprague Dawley rats aged 4-5 weeks, and then cultured with GO-CMC hydrogels with and without different cytokines, respectively. CD206 immunofluorescence staining was used to detect the differentiation of macrophages after 24 hours. The 3rd generation of rats BMSCs were cultured with GO-CMC hydrogels with and without different cytokines respectively for osteogenic induction. The early osteogenesis was observed by alkaline phosphatase (ALP) staining after 10 days, and the late osteogenesis was observed by alizarin red staining after 21 days.Results Generally, GO-CMC hydrogel was brown and translucent. SEM showed that the pore diameter and wall thickness of GO-CMC hydrogel were similar to that of CMC hydrogel, but the inner wall roughness increased. FTIR test showed that CMC polymerized to form hydrogel. In vitro, the sustained release experiments showed that the properties of GO-CMC hydrogels loaded with different cytokines were similar. CD206 immunofluorescence detection showed that GO-CMC hydrogels could induce macrophages differentiation into M2-type. ALP and alizarin red staining showed that GO-CMC hydrogels could induce BMSCs osteogenic differentiation, in which GO-CMC hydrogel loaded with IL-4+BMP-2 showed the most significant effect (P<0.05).Conclusion The GO-CMC hydrogel loaded with IL-4 and BMP-2 can induce macrophages differentiation into M2-type and enhance the ability of BMSCs with osteogenic differentiation in vitro, which provide a new strategy for bone defect repair and immune regulation.

Citation： ZOU Min, SUN Jiachen, XIANG Zhou. Early effect of graphene oxide-carboxymethyl chitosan hydrogel loaded with interleukin 4 and bone morphogenetic protein 2 on bone immunity and repair. Chinese Journal of Reparative and Reconstructive Surgery, 2020, 34(8): 1044-1051. doi: 10.7507/1002-1892.201911068 Copy

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3.	Chen P, Piao X, Bonaldo P. Role of macrophages in Wallerian degeneration and axonal regeneration after peripheral nerve injury. Acta Neuropathol, 2015, 130(5): 605-618.
4.	Pajarinen J, Lin T, Gibon E, et al. Mesenchymal stem cell-macrophage crosstalk and bone healing. Biomaterials, 2019, 196: 80-89.
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9.	Jing X, Mi HY, Napiwocki BN, et al. Mussel-inspired electroactive chitosan/graphene oxide composite hydrogel with rapid self-healing and recovery behavior for tissue engineering. Carbon, 2017, 125: 557-570.
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11.	Sun X, Liu Z, Welsher K, et al. Nano-graphene oxide for cellular imaging and drug delivery. Nano Res, 2008, 1(3): 203-212.
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13.	Zhang W, Zhao F, Huang D, et al. Strontium-substituted submicrometer bioactive glasses modulate macrophage responses for improved bone regeneration. ACS Appl Mater Interfaces, 2016, 8(45): 30747-30758.
14.	Zhang Q, Hubenak J, Iyyanki T, et al. Engineering vascularized soft tissue flaps in an animal model using human adipose-derived stem cells and VEGF+PLGA/PEG microspheres on a collagen-chitosan scaffold with a flow-through vascular pedicle. Biomaterials, 2015, 73: 198-213.
15.	Reeves AR, Spiller KL, Freytes DO, et al. Controlled release of cytokines using silk-biomaterials for macrophage polarization. Biomaterials, 2015, 73: 272-283.
16.	Ahmed S, Ikram S. Chitosan & its derivatives: a review in recent innovations. IJPSR, 2015, 6(1): 14-30.
17.	Wang K, Ruan J, Song H, et al. Biocompatibility of graphene oxide. Nanoscale Res Lett, 2011, 6(1): 8.
18.	Ruan J, Wang XS, Yu Z, et al. Enhanced physiochemical and mechanical performance of chitosan-grafted graphene oxide for superior osteoinductivity. Adv Funct Mater, 2016, 26(7): 1085-1097.
19.	Mori G, D’Amelio P, Faccio R, et al. The interplay between the bone and the immune system. Clin Dev Immunol, 2013, 2013: 720504.
20.	Zheng ZW, Chen YH, Wu DY, et al. Development of an accurate and proactive immunomodulatory strategy to improve bone substitute material-mediated osteogenesis and angiogenesis. Theranostics, 2018, 8(19): 5482-5500.
21.	Madl CM, Mehta M, Duda GN, et al. Presentation of BMP-2 mimicking peptides in 3D hydrogels directs cell fate commitment in osteoblasts and mesenchymal stem cells. Biomacromolecules, 2014, 15(2): 445-455.
22.	Sun J, Zhang Y, Li B, et al. Controlled release of BMP-2 from a collagen-mimetic peptide-modified silk fibroin-nanohydroxyapatite scaffold for bone regeneration. J Mater Chem B, 2017, 5(44): 8770-8779.
23.	Champagne CM, Takebe J, Offenbacher S, et al. Macrophage cell lines produce osteoinductive signals tha include bone morphogenetic protein-2. Bone, 2002, 30(1): 26-31.
24.	Guihard P, Danger Y, Brounais B, et al. Induction of osteogenesis in mesenchymal stem cells by activated monocytes/macrophages depends on oncostatin M signaling. Stem Cells, 2012, 30(4): 762-772.
25.	Gibon E, Lu L, Goodman SB. Aging, inflammation, stem cells, and bone healing. Stem Cell Res Ther, 2016, 7: 44.
26.	Zhang Y, Böse T, Unger RE, et al. Macrophage type modulates osteogenic differentiation of adipose tissue MSCs. Cell Tissue Res, 2017, 369(2): 273-286.
27.	He XT, Li X, Yin Y, et al. The effects of conditioned media generated by polarized macrophages on the cellular behaviours of bone marrow mesenchymal stem cells. J Cell Mol Med, 2018, 22(2): 1302-1315.
28.	He XT, Li X, Xia Y, et al. Building capacity for macrophage modulation and stem cell recruitment in high-stiffness hydrogels for complex periodontal regeneration: experimental studies in vitro and in rats. Acta Biomater, 2019, 88: 162-180.
29.	Lin T, Pajarinen J, Nabeshima A, et al. Establishment of NF-κB sensing and interleukin-4 secreting mesenchymal stromal cells as an “on-demand” drug delivery system to modulate inflammation. Cytotherapy, 2017, 19(9): 1025-1034.
30.	Shu Y, Yu Y, Zhang S, et al. The immunomodulatory role of sulfated chitosan in BMP-2-mediated bone regeneration. Biomater Sci, 2018, 6(9): 2496-2507.

1. Chen Z, Wu C, Gu W, et al. Osteogenic differentiation of bone marrow MSCs by β-tricalcium phosphate stimulating macrophages via BMP2 signaling pathway. Biomaterials, 2014, 35(5): 1507-1518.
2. Ferrante CJ, Pinhal-Enfield G, Elson G, et al. The adenosine-dependent angiogenic switch of macrophages to an M2-like phenotype is independent of interleukin-4 receptor alpha (IL-4 Ralpha) signaling. Inflammation, 2013, 36(4): 921-931.
3. Chen P, Piao X, Bonaldo P. Role of macrophages in Wallerian degeneration and axonal regeneration after peripheral nerve injury. Acta Neuropathol, 2015, 130(5): 605-618.
4. Pajarinen J, Lin T, Gibon E, et al. Mesenchymal stem cell-macrophage crosstalk and bone healing. Biomaterials, 2019, 196: 80-89.
5. Travis J. Method of cancer treatment. Science, 1992, 258(5): 1732-1733.
6. Upadhyaya L, Singh J, Agarwal V, et al. The implications of recent advances in carboxymethyl chitosan based targeted drug delivery and tissue engineering applications. J Control Release, 2014, 186: 54-87.
7. Slavchov RI, Novev JK. Surface tension of concentrated electrolyte solution. J Colloid Interface Sci, 2012, 387(1): 234-243.
8. Liu X, Miller AL 2nd, Park S, et al. Functionalized carbon nanotube and graphene oxide embedded electrically conductive hydrogel synergistically stimulates nerve cell differentiation. ACS Appl Mater Interfaces, 2017, 9(17): 14677-14690.
9. Jing X, Mi HY, Napiwocki BN, et al. Mussel-inspired electroactive chitosan/graphene oxide composite hydrogel with rapid self-healing and recovery behavior for tissue engineering. Carbon, 2017, 125: 557-570.
10. Park J, Kim B, Han J, et al. Graphene oxide flakes as a cellular adhesive: prevention of reactive oxygen species mediated death of implanted cells for cardiac repair. ACS Nano, 2015, 9(5): 4987-4999.
11. Sun X, Liu Z, Welsher K, et al. Nano-graphene oxide for cellular imaging and drug delivery. Nano Res, 2008, 1(3): 203-212.
12. Lee SS, Huang BJ, Kaltz SR, et al. Bone regeneration with low dose BMP-2 amplified by biomimetic supramolecular nanofibers within collagen scaffolds. Biomaterials, 2013, 34(2): 452-459.
13. Zhang W, Zhao F, Huang D, et al. Strontium-substituted submicrometer bioactive glasses modulate macrophage responses for improved bone regeneration. ACS Appl Mater Interfaces, 2016, 8(45): 30747-30758.
14. Zhang Q, Hubenak J, Iyyanki T, et al. Engineering vascularized soft tissue flaps in an animal model using human adipose-derived stem cells and VEGF+PLGA/PEG microspheres on a collagen-chitosan scaffold with a flow-through vascular pedicle. Biomaterials, 2015, 73: 198-213.
15. Reeves AR, Spiller KL, Freytes DO, et al. Controlled release of cytokines using silk-biomaterials for macrophage polarization. Biomaterials, 2015, 73: 272-283.
16. Ahmed S, Ikram S. Chitosan & its derivatives: a review in recent innovations. IJPSR, 2015, 6(1): 14-30.
17. Wang K, Ruan J, Song H, et al. Biocompatibility of graphene oxide. Nanoscale Res Lett, 2011, 6(1): 8.
18. Ruan J, Wang XS, Yu Z, et al. Enhanced physiochemical and mechanical performance of chitosan-grafted graphene oxide for superior osteoinductivity. Adv Funct Mater, 2016, 26(7): 1085-1097.
19. Mori G, D’Amelio P, Faccio R, et al. The interplay between the bone and the immune system. Clin Dev Immunol, 2013, 2013: 720504.
20. Zheng ZW, Chen YH, Wu DY, et al. Development of an accurate and proactive immunomodulatory strategy to improve bone substitute material-mediated osteogenesis and angiogenesis. Theranostics, 2018, 8(19): 5482-5500.
21. Madl CM, Mehta M, Duda GN, et al. Presentation of BMP-2 mimicking peptides in 3D hydrogels directs cell fate commitment in osteoblasts and mesenchymal stem cells. Biomacromolecules, 2014, 15(2): 445-455.
22. Sun J, Zhang Y, Li B, et al. Controlled release of BMP-2 from a collagen-mimetic peptide-modified silk fibroin-nanohydroxyapatite scaffold for bone regeneration. J Mater Chem B, 2017, 5(44): 8770-8779.
23. Champagne CM, Takebe J, Offenbacher S, et al. Macrophage cell lines produce osteoinductive signals tha include bone morphogenetic protein-2. Bone, 2002, 30(1): 26-31.
24. Guihard P, Danger Y, Brounais B, et al. Induction of osteogenesis in mesenchymal stem cells by activated monocytes/macrophages depends on oncostatin M signaling. Stem Cells, 2012, 30(4): 762-772.
25. Gibon E, Lu L, Goodman SB. Aging, inflammation, stem cells, and bone healing. Stem Cell Res Ther, 2016, 7: 44.
26. Zhang Y, Böse T, Unger RE, et al. Macrophage type modulates osteogenic differentiation of adipose tissue MSCs. Cell Tissue Res, 2017, 369(2): 273-286.
27. He XT, Li X, Yin Y, et al. The effects of conditioned media generated by polarized macrophages on the cellular behaviours of bone marrow mesenchymal stem cells. J Cell Mol Med, 2018, 22(2): 1302-1315.
28. He XT, Li X, Xia Y, et al. Building capacity for macrophage modulation and stem cell recruitment in high-stiffness hydrogels for complex periodontal regeneration: experimental studies in vitro and in rats. Acta Biomater, 2019, 88: 162-180.
29. Lin T, Pajarinen J, Nabeshima A, et al. Establishment of NF-κB sensing and interleukin-4 secreting mesenchymal stromal cells as an “on-demand” drug delivery system to modulate inflammation. Cytotherapy, 2017, 19(9): 1025-1034.
30. Shu Y, Yu Y, Zhang S, et al. The immunomodulatory role of sulfated chitosan in BMP-2-mediated bone regeneration. Biomater Sci, 2018, 6(9): 2496-2507.

Chinese Journal of Reparative and Reconstructive Surgery

Early effect of graphene oxide-carboxymethyl chitosan hydrogel loaded with interleukin 4 and bone morphogenetic protein 2 on bone immunity and repair

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