Promising application of magnetic nanoparticles and electromagnetic fields in articular cartilage-related diseases: an overview

Masoumeh Haghbin Nazarpak

Promising application of magnetic nanoparticles and electromagnetic fields in articular cartilage-related diseases: an overview

محل انتشار: Journal of Applied Tissue Engineering، دوره: 8، شماره: 1

سال انتشار: 1400

نوع سند: مقاله ژورنالی

زبان: انگلیسی

مشاهده: 14

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https://civilica.com/doc/2474696

شناسه ملی سند علمی:

JR_JATE-8-1_001

تاریخ نمایه سازی: 14 دی 1404

چکیده مقاله:

Articular cartilage-related diseases are a growing problem worldwide. Although there are several therapeutic options available for these diseases, the repair of damaged articular cartilage remains an intractable issue. Therefore, a strong need exists for new approaches such as offered by tissue engineering. However, this approach is also associated with some drawbacks including poor regeneration of cultured cells. Recently, magnetic nanoparticles and electromagnetic fields (EMFs) have been suggested to influence on different cellular processes such as proliferation and differentiation and thus are able to overcome these drawbacks of tissue engineering. In this article, we review the current knowledge on the definition and characteristics of magnetic nanoparticles and EMFs. We also discuss the beneficial effects of magnetic nanoparticles and EMFs in various in vitro and in vivo studies.Articular cartilage-related diseases are a growing problem worldwide. Although there are several therapeutic options available for these diseases, the repair of damaged articular cartilage remains an intractable issue. Therefore, a strong need exists for new approaches such as offered by tissue engineering. However, this approach is also associated with some drawbacks including poor regeneration of cultured cells. Recently, magnetic nanoparticles and electromagnetic fields (EMFs) have been suggested to influence on different cellular processes such as proliferation and differentiation and thus are able to overcome these drawbacks of tissue engineering. In this article, we review the current knowledge on the definition and characteristics of magnetic nanoparticles and EMFs. We also discuss the beneficial effects of magnetic nanoparticles and EMFs in various in vitro and in vivo studies.

نویسندگان

Masoumeh Haghbin Nazarpak

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He, Y.J., S. Lin, and Q. Ao, Research Progress of ...
Carballo, C.B., et al., Basic science of articular cartilage. Clinics ...
Sophia Fox, A.J., A. Bedi, and S.A. Rodeo, The basic ...
Decker, R.S., E. Koyama, and M. Pacifici, Articular cartilage: structural ...
Ruggiero, L., et al., Roles of the fibrous superficial zone ...
Chen, S., et al., Meniscus, articular cartilage and nucleus pulposus: ...
Camarero-Espinosa, S., et al., Articular cartilage: from formation to tissue ...
Lopez-Ruiz, E., et al., Polymers, scaffolds and bioactive molecules with ...
Gilbert, S.J., and E.J. Blain, Cartilage mechanobiology: How chondrocytes respond ...
Armiento, A., et al., Biomaterials for articular cartilage tissue engineering: ...
Makris, E.A., et al., Repair and tissue engineering techniques for ...
Hunziker, E.B., et al., An educational review of cartilage repair: ...
Bannuru, R.R., et al., OARSI guidelines for the non-surgical management ...
Tatullo, M., M. Marrelli, and F. Paduano, The regenerative medicine ...
Mason, C., and P. Dunnill, A brief definition of regenerative ...
Bhardwaj, N., D. Devi, and B.B. Mandal, Tissue‐engineered cartilage: The ...
Gupta, P., et al., Biomimetic, osteoconductive non-mulberry silk fiber reinforced ...
Mondschein, R.J., et al., Polymer structure-property requirements for stereolithographic 3D ...
Ma, F., et al., Accelerating proliferation of neural stem/progenitor cells ...
Chen, G., et al., Application of the cell sheet technique ...
Love, M.R., et al., Effects of electrical stimulation on cell ...
Ding, S., et al., Modulation of human mesenchymal and pluripotent ...
Morgan, J.T., et al., Integration of basal topographic cues and ...
Yang, Y., et al., Biophysical regulation of cell behavior—cross talk ...
Zhang, S.X., L. Liu, and W. Zhao, Targeting biophysical cues: ...
Gao, J., et al., Biomimetic stochastic topography and electric fields ...
Huang, X., et al., Physical stimulations for bone and cartilage ...
Balint, R., N.J. Cassidy, and S.H.Cartmell, Electrical stimulation: a novel ...
Wang, E.T., and Z. Min, Regulation of tissue repair and ...
Chen, C., X. Kong, and I.S. Lee, Modification of surface/neuron ...
McBain, S.C., H.H. Yiu, and J. Dobson, Magnetic nanoparticles for ...
Neuberger, T., et al., Superparamagnetic nanoparticles for biomedical applications: possibilities ...
Alexiou, C., et al., Medical applications of magnetic nanoparticles. Journal ...
Crick, F., and A. Hughes, The physical properties of cytoplasm. ...
Titushkin, I., and M. Cho, Modulation of cellular mechanics during ...
Yanagisawa, M., et al., Effects of compressive force on the ...
Ito, A., et al., The effect of RGD peptide-conjugated magnetite ...
Ito, A., et al. Novel methodology for fabrication of tissue-engineered ...
Shimizu, K., A. Ito, and H. Honda, Enhanced cell‐seeding into ...
Kobayashi, T., et al. A novel cell delivery system using ...
Kobayashi, T., et al. Augmentation of degenerated human cartilage in ...
Zhang, N., et al., Magnetic nanocomposite hydrogel for potential cartilage ...
Luciani, N., et al. Successful chondrogenesis within scaffolds, using magnetic ...
Huang, J., et al. Development of magnetic nanocomposite hydrogel with ...
Kim, K.E., et al., Potential therapeutic mechanism of extremely low-frequency ...
Halliday, D., R. Resnick, and J. Walker, Fundamentals of Physics: ...
Kumar, S., S. Dey, and S. Jain. Extremely low-frequency electromagnetic ...
Ahlbom, A., et al. Possible effects of electromagnetic fields (EMF) ...
Spencer, J.N., G.M. Bodner, and L.H. Rickard, Chemistry: Structure and ...
Markov, M.S., Magnetic field therapy: a review. Electromagnetic Biology and ...
Glab, G., et al., Static or dynamic low-frequency magnetic field? ...
Sakai, A., et al., Effects of pulsing electromagnetic fields on ...
De Mattei, M., et al., Effects of pulsed electromagnetic fields ...
De Mattei, M., et al., Effects of electromagnetic fields on ...
De Mattei, M., et al., Effects of physical stimulation with ...
Nicolin, V., et al., In vitro exposure of human chondrocytes ...
Sun, L.Y., et al., Effect of pulsed electromagnetic field on ...
Mayer-Wagner, S., et al., Effects of low frequency electromagnetic fields ...
Ongaro A., et al., Electromagnetic fields counteract IL-1b activity during ...
Esposito, M., et al., Differentiation of human umbilical cord-derived mesenchymal ...
Chen, C.H., et al., Electromagnetic fields enhance chondrogenesis of human ...
Hilz, F.M., et al., Influence of extremely low frequency, low ...
Yi, H.G., et al., Effects of electromagnetic field frequencies on ...
T. Saito, Y.M., and E. Nakamachi. Effect of the Gradient ...
Kavand, H., et al., Extremely Low Frequency Electromagnetic Field in ...
Parate, D., et al., Enhancement of mesenchymal stem cell chondrogenesis ...
Redeker, J.I., et al., Effect of electromagnetic fields on human ...
Tu, C., et al., The legacy effects of electromagnetic fields ...
Mayer-Wagner, S., et al., Effects of single and combined low ...
Huang, J., et al., Magnetic Enhancement of Chondrogenic Differentiation of ...
Escobar, J.F., et al., In Vitro Evaluation of the Effect ...
Ciombor, D.M., et al., Modification of osteoarthritis by pulsed electromagnetic ...
Fini, M., et al., Effect of pulsed electromagnetic field stimulation ...
Boopalan, P., et al., Pulsed electromagnetic field (PEMF) treatment for ...
Fernando, S.B., et al., Effects of pulsed electromagnetic fields on ...
Boopalan, P., et al., Pulsed electromagnetic field therapy results in ...
Sotelo-Barroso, F., et al., PEMF effects on chondrocyte cellularity and ...
Parate, D., et al., Pulsed electromagnetic fields potentiate the paracrine ...
Stefani, R.M., et al., Pulsed electromagnetic fields promote repair of ...

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