Improving the osteogenesis of human bone marrow mesenchymal stem cell sheets by microRNA-21-loaded chitosan/hyaluronic acid nanoparticles via reverse transfection

Wang, Zhongshan; Wu, Guangsheng; Wei, Mengying; Liu, Qian; Zhou, Jian; Qin, Tian; Feng, Xiaoke; Liu, Huan; Feng, Zhihong; Zhao, Yimin

doi:10.2147/ijn.s104851

Cited by 22 publications

(13 citation statements)

References 35 publications

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“…A number of miRNAs enhance the osteogenic differentiation of MSCs; hence, they have been pointed out as potential therapies to promote bone regeneration. For example, scaffolds and particles loaded with analogs of miR‐21 or miR‐148 potentiate bone regeneration in experimental models, at least in part, by interacting with the RUNX2 pathway . On the other hand, anti‐sense oligonucleotides and “sponges” inhibiting miR‐22, miR‐29, miR‐31, miR‐133, miR‐138, or miR‐214 have a stimulatory effect on osteogenesis and may improve fracture healing .…”

Section: Non‐coding Rnas In Skeletal Disordersmentioning

confidence: 99%

Role of Epigenomics in Bone and Cartilage Disease

Meurs

Boer

López-Delgado

et al. 2019

Journal of Bone and Mineral Research

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Phenotypic variation in skeletal traits and diseases is the product of genetic and environmental factors. Epigenetic mechanisms include information-containing factors, other than DNA sequence, that cause stable changes in gene expression and are maintained during cell divisions. They represent a link between environmental influences, genome features, and the resulting phenotype. The main epigenetic factors are DNA methylation, posttranslational changes of histones, and higher-order chromatin structure. Sometimes non-coding RNAs, such as microRNAs (miRNAs) and long non-coding RNAs (lncRNAs), are also included in the broad term of epigenetic factors. There is rapidly expanding experimental evidence for a role of epigenetic factors in the differentiation of bone cells and the pathogenesis of skeletal disorders, such as osteoporosis and osteoarthritis. However, different from genetic factors, epigenetic signatures are cell-and tissue-specific and can change with time. Thus, elucidating their role has particular difficulties, especially in human studies. Nevertheless, epigenomewide association studies are beginning to disclose some disease-specific patterns that help to understand skeletal cell biology and may lead to development of new epigenetic-based biomarkers, as well as new drug targets useful for treating diffuse and localized disorders. Here we provide an overview and update of recent advances on the role of epigenomics in bone and cartilage diseases.Besides chromatin-related marks and structure, non-coding RNAs (ncRNAs) are also frequently included among the mechanisms of epigenetic control. (8) They are classified as small RNAs (<200 nucleotides) and long RNAs (>200 nucleotides). The best-known subset of small RNAs are microRNAs (miRNAs, 18 to 25 nucleotides), which inhibit protein synthesis by binding to the 3 0 -untranslated region of target mRNAs. Long non-coding RNAs (lncRNAs) modulate the activity of both nearby genes and distant genes by a variety of mechanisms. For instance, they often serve as scaffolds for transcription factors and other molecules involved in initiation of transcription, including Box 1. Epigenomics-Related TermsChromatin: The complex of DNA and its packaging molecules. The core of the chromatin is the nucleosome, which consists of an octamer of 4 histones around which 147 bp of DNA is wrapped around.Chromosome conformation capture and Hi-C: Techniques used to map the spatial (3D) organization of the chromatin in the nucleus. Chromosome conformation capture (3C) quantifies the number of interactions between a given loci and the rest of the genome. In Hi-C, all genomic interaction between all genomic regions are quantified.CTCF: CCCTC-binding factor, highly conserved zinc finger protein involved in diverse genomic regulatory functions, including transcriptional activation/repression, insulation, imprinting, and X-chromosome inactivation, through mediating the formation of chromatin loops. DNA methyl-transferases (DNMTs): Family of enzymes responsible for the methylation of DNA. DNMT1...

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Section: Non‐coding Rnas In Skeletal Disordersmentioning

confidence: 99%

Role of Epigenomics in Bone and Cartilage Disease

Meurs

Boer

López-Delgado

et al. 2019

Journal of Bone and Mineral Research

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“…There are ongoing investigations to obtain the best results in bone regeneration with MSC sheets. Some of the biomaterials and/or biological agents reported to be combined with MSC sheets to enhance osteogenesis include coral particles [ 47 ], ceramics [ 48 ], surface-modified titanium and zirconia [ 82 ], simvastatin [ 83 ], β -tricalcium phosphate [ 84 ], coumarin-like derivative osthole [ 85 ], CD34+ peripheral blood cells [ 86 ], a complex of polyethylenimine-alginate nanocomposites plus BMP2 gene [ 87 ], nonviral oligonucleotide antimiR-138 delivery to MSC sheets [ 88 ], platelet-rich fibrin [ 89 , 90 ], vitamin C [ 91 ], poly(dimethylsiloxane) surface silanization [ 92 ], stromal cell-derived factor-1 [ 93 ], microRNA-21-loaded chitosan/hyaluronic acid nanoparticles [ 94 ], hydroxyapatite particles [ 90 , 95 ], and Notch activation by Jagged1 in MSC sheet cultures [ 96 ].…”

Section: The Use Of Msc Sheets In Combination With Scaffolds And/omentioning

confidence: 99%

A Concise Review on the Use of Mesenchymal Stem Cells in Cell Sheet-Based Tissue Engineering with Special Emphasis on Bone Tissue Regeneration

Yörükoğlu

Kiter

Akkaya

et al. 2017

Stem Cells International

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The integration of stem cell technology and cell sheet engineering improved the potential use of cell sheet products in regenerative medicine. This review will discuss the use of mesenchymal stem cells (MSCs) in cell sheet-based tissue engineering. Besides their adhesiveness to plastic surfaces and their extensive differentiation potential in vitro, MSCs are easily accessible, expandable in vitro with acceptable genomic stability, and few ethical issues. With all these advantages, they are extremely well suited for cell sheet-based tissue engineering. This review will focus on the use of MSC sheets in osteogenic tissue engineering. Potential application techniques with or without scaffolds and/or grafts will be discussed. Finally, the importance of osteogenic induction of these MSC sheets in orthopaedic applications will be demonstrated.

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“…used a microarc-oxidized titanium surface with miRNA-21loaded hyaluronic acid nanoparticles, and they confirmed that this scaffold promotes osteogenic differentiation on human bone marrow mesenchymal stem cells. [44][45][46] There are no clinical trials entries using miRNAs or antagomirs as bone diseases therapy in clinicaltrial.gov to date. However, there is study from Moscow State University started in 2017, that evaluates the safety and efficacy of a gene-activated bone substitute consisting of octacalcium phosphate and plasmid DNA encoding vascular endothelial growth factor for maxillofacial bone regeneration.…”

Section: Inhibit Bone Formation and Differentiationmentioning

confidence: 99%