Citations (47)
Keep up to date with the latest research on this topic with citation updates for this article.
Read on this site (5)
Ana C. Manjua, Joaquim M. S. Cabral, Carla A. M. Portugal & Frederico Castelo Ferreira. (2021) Magnetic stimulation of the angiogenic potential of mesenchymal stromal cells in vascular tissue engineering. Science and Technology of Advanced Materials 22:1, pages 461-480.
Read now
Read now
Mohammad Samiei, Zahra Aghazadeh, Elaheh Dalir Abdolahinia, Amin Vahdati, Sabalan Daneshvar & Atefe Noghani. (2020) The effect of electromagnetic fields on survival and proliferation rate of dental pulp stem cells. Acta Odontologica Scandinavica 78:7, pages 494-500.
Read now
Read now
Jing-Yau Tang, Te-Wei Yeh, Yu-Ting Huang, Min-Haw Wang & Ling-Sheng Jang. (2019) Effects of extremely low-frequency electromagnetic fields on B16F10 cancer cells. Electromagnetic Biology and Medicine 38:2, pages 149-157.
Read now
Read now
Wei Wang, Wenkai Li, Mingyu Song, Sheng Wei, Chaoxu Liu, Yong Yang & Hua Wu. (2016) Effects of electromagnetic fields on the metabolism of lubricin of rat chondrocytes. Connective Tissue Research 57:2, pages 152-160.
Read now
Read now
Juan C Chachques, Manuel Monleon Pradas, Antoni Bayes-Genis & Carlos Semino. (2013) Creating the bioartificial myocardium for cardiac repair: challenges and clinical targets. Expert Review of Cardiovascular Therapy 11:12, pages 1701-1711.
Read now
Read now
Articles from other publishers (42)
Tian Ma, Qing Ding, Chaoxu Liu & Hua Wu. (2023) Electromagnetic fields regulate calcium-mediated cell fate of stem cells: osteogenesis, chondrogenesis and apoptosis. Stem Cell Research & Therapy 14:1.
Crossref
Crossref
Xinmiao Ji & Xin Zhang. 2023. Biological Effects of Static Magnetic Fields. Biological Effects of Static Magnetic Fields
133
185
.
Yuling Chen & Shike Hou. (2022) Application of magnetic nanoparticles in cell therapy. Stem Cell Research & Therapy 13:1.
Crossref
Crossref
Atiyeh Sadat Safavi, Anna Sendera, Nooshin Haghighipour & Agnieszka Banas-Zabczyk. (2022) The Role of Low-Frequency Electromagnetic Fields on Mesenchymal Stem Cells Differentiation: A Systematic Review. Tissue Engineering and Regenerative Medicine 19:6, pages 1147-1160.
Crossref
Crossref
Luminita Labusca, Camelia Danceanu, Anca Emanuela Minuti, Dumitru-Daniel Herea, Adrian Ghemes, Cristian Rotarescu, Oana Dragos-Pinzaru, Mihai Tibu, Grigoras Marian, Horia Chiriac & Nicoleta Lupu. (2022) Magnetic nanowires substrate increases adipose-derived mesenchymal cells osteogenesis. Scientific Reports 12:1.
Crossref
Crossref
Haokaifeng Wu, Chuang Li, Muqaddas Masood, Zhen Zhang, Esther González-Almela, Alvaro Castells-Garcia, Gaoyang Zou, Xiaoduo Xu, Luqin Wang, Guoqing Zhao, Shengyong Yu, Ping Zhu, Bo Wang, Dajiang Qin & Jing Liu. (2022) Static Magnetic Fields Regulate T-Type Calcium Ion Channels and Mediate Mesenchymal Stem Cells Proliferation. Cells 11:15, pages 2460.
Crossref
Crossref
Massimo E. Maffei. (2022) Magnetic Fields and Cancer: Epidemiology, Cellular Biology, and Theranostics. International Journal of Molecular Sciences 23:3, pages 1339.
Crossref
Crossref
Haslinda Abdul Hamid, Vahid Hosseinpour Sarmadi, Vivek Prasad, Rajesh Ramasamy & Azizi Miskon. (2022) Electromagnetic field exposure as a plausible approach to enhance the proliferation and differentiation of mesenchymal stem cells in clinically relevant scenarios电磁场暴露作为在临床相关情况下增强间充质干细胞增殖和分化的一种可行方法. Journal of Zhejiang University-SCIENCE B 23:1, pages 42-57.
Crossref
Crossref
Abeer Sallam, Thangirala Sudha, Noureldien H.E. Darwish, Samar Eghotny, Abeer E-Dief, Passainte S. Hassaan & Shaker A. Mousa. (2021) In vitro differentiation of human bone marrow stromal cells into neural precursor cells using small molecules. Journal of Neuroscience Methods 363, pages 109340.
Crossref
Crossref
Aditya Kumar SharmaShrutika SahSuresh Kumar SinglaManmohan Singh ChauhanRadhey Shyam ManikPrabhat Palta. (2021)
Exposure to Pulsed Electromagnetic Fields Improves the Developmental Competence and Quality of Somatic Cell Nuclear Transfer Buffalo (
Bubalus bubalis
) Embryos Produced Using Fibroblast Cells and Alters Their Epigenetic Status and Gene Expression
. Cellular Reprogramming 23:5, pages 304-315.
Crossref
Crossref
Ana C. Manjua, Joaquim M. S. Cabral, Frederico Castelo Ferreira & Carla A. M. Portugal. (2021) Magnetic Field Dynamic Strategies for the Improved Control of the Angiogenic Effect of Mesenchymal Stromal Cells. Polymers 13:11, pages 1883.
Crossref
Crossref
Tayebeh Sadat Tabatabai, Maryam Haji Ghasem Kashani, Reza Maskani, Meysam Nasiri, Seyyed Ahmad Nabavi Amri, Amir Atashi & Fateme Sadat Bitaraf. (2021) Synergic effects of extremely low-frequency electromagnetic field and betaine on in vitro osteogenic differentiation of human adipose tissue-derived mesenchymal stem cells. In Vitro Cellular & Developmental Biology - Animal 57:4, pages 468-476.
Crossref
Crossref
Kornelia Łach, Cebulski Józef, Chaber Radosław, Kocan Beata, Wojnarowska-Nowak Renata & Banaś-Ząbczyk Agnieszka. (2021) First identification of the effects of low frequency electromagnetic field on the micromolecular changes in adipose tissue-derived mesenchymal stem cells by fourier transform infrared spectroscopy. Journal of Medical Physics 0:0, pages 0.
Crossref
Crossref
Guilin Chen, Yujuan Zhuo, Bo Tao, Qian Liu, Wenlong Shang, Yinxiu Li, Yuhong Wang, Yanli Li, Lei Zhang, Yanwen Fang, Xin Zhang, Zhicai Fang & Ying Yu. (2020) Moderate SMFs attenuate bone loss in mice by promoting directional osteogenic differentiation of BMSCs. Stem Cell Research & Therapy 11:1.
Crossref
Crossref
Atena Shapourzadeh, Seyed-Mohammad Atyabi, Shiva Irani & Hadi Bakhshi. (2020) Osteoinductivity of polycaprolactone nanofibers grafted functionalized with carboxymethyl chitosan: Synergic effect of β-carotene and electromagnetic field. International Journal of Biological Macromolecules 150, pages 152-160.
Crossref
Crossref
Ga-Eun Ki, Yu-Mi Kim, Han-Moi Lim, Eun-Cheol Lee, Yun-Kyong Choi & Young-Kwon Seo. (2020) Extremely Low-Frequency Electromagnetic Fields Increase the Expression of Anagen-Related Molecules in Human Dermal Papilla Cells via GSK-3β/ERK/Akt Signaling Pathway. International Journal of Molecular Sciences 21:3, pages 784.
Crossref
Crossref
Juan Felipe Escobar, Juan Jairo Vaca‐González, Johana Maria Guevara, Jose Félix Vega, Yoshie Adriana Hata & Diego Alexander Garzón‐Alvarado. (2019) In Vitro Evaluation of the Effect of Stimulation with Magnetic Fields on Chondrocytes. Bioelectromagnetics 41:1, pages 41-51.
Crossref
Crossref
Huaixi Wang, Xiangyu Tang, Wenkai Li, Jingyuan Chen, Hao Li, Jiyuan Yan, Xuefeng Yuan, Hua Wu & Chaoxu Liu. (2019) Enhanced osteogenesis of bone marrow stem cells cultured on hydroxyapatite/collagen I scaffold in the presence of low-frequency magnetic field. Journal of Materials Science: Materials in Medicine 30:8.
Crossref
Crossref
Vyacheslav A. Ryzhov, Gabriele Multhoff & Maxim A. Shevtsov. (2019) Detection of Magnetosome-Like Structures in Eukaryotic Cells Using Nonlinear Longitudinal Response to ac Field. Applied Magnetic Resonance 50:8, pages 943-957.
Crossref
Crossref
Krzysztof Marycz, K. Kornicka & M. Röcken. (2018) Static Magnetic Field (SMF) as a Regulator of Stem Cell Fate – New Perspectives in Regenerative Medicine Arising from an Underestimated Tool. Stem Cell Reviews and Reports 14:6, pages 785-792.
Crossref
Crossref
Ilona Uzieliene, Paulius Bernotas, Ali Mobasheri & Eiva Bernotiene. (2018) The Role of Physical Stimuli on Calcium Channels in Chondrogenic Differentiation of Mesenchymal Stem Cells. International Journal of Molecular Sciences 19:10, pages 2998.
Crossref
Crossref
Ezzatollah Fathi & Raheleh Farahzadi. (2017) Zinc Sulphate Mediates the Stimulation of Cell Proliferation of Rat Adipose Tissue-Derived Mesenchymal Stem Cells Under High Intensity of EMF Exposure. Biological Trace Element Research 184:2, pages 529-535.
Crossref
Crossref
Zhimin Chen, Mang I Vai, Sio Hang Pun & Peng Un Mak. (2018) Electromagnetic Field Analysis of Low-Magnitude High-Frequency Vibrator with Multiple Plungers. Electromagnetic Field Analysis of Low-Magnitude High-Frequency Vibrator with Multiple Plungers.
Liliana Polo-Corrales, Jaime Ramirez-Vick & Jhon Jairo Feria-Diaz. (2018) Recent Advances in Biophysical stimulation of MSC for bone regeneration. Indian Journal of Science and Technology 11:15, pages 1-41.
Crossref
Crossref
Carly A. Buckner, Alison L. Buckner, Stan A. Koren, Michael A. Persinger & Robert M. Lafrenie. (2017) Exposure to a specific time‐varying electromagnetic field inhibits cell proliferation via cAMP and ERK signaling in cancer cells. Bioelectromagnetics 39:3, pages 217-230.
Crossref
Crossref
Przemyslaw Solek, Lena Majchrowicz, Dominika Bloniarz, Ewelina Krotoszynska & Marek Koziorowski. (2017) Pulsed or continuous electromagnetic field induce p53/p21-mediated apoptotic signaling pathway in mouse spermatogenic cells in vitro and thus may affect male fertility. Toxicology 382, pages 84-92.
Crossref
Crossref
Ezzatollah Fathi & Raheleh Farahzadi. (2017) Enhancement of osteogenic differentiation of rat adipose tissue-derived mesenchymal stem cells by zinc sulphate under electromagnetic field via the PKA, ERK1/2 and Wnt/β-catenin signaling pathways. PLOS ONE 12:3, pages e0173877.
Crossref
Crossref
Jasmin Nurković, Ivan Zaletel, Selmina Nurković, Šefćet Hajrović, Fahrudin Mustafić, Jovan Isma, Aleksandra Jurišić Škevin, Vesna Grbović, Milica Kovačević Filipović & Zana Dolićanin. (2016) Combined effects of electromagnetic field and low-level laser increase proliferation and alter the morphology of human adipose tissue-derived mesenchymal stem cells. Lasers in Medical Science 32:1, pages 151-160.
Crossref
Crossref
Xin Zhang, Kevin Yarema & An XuXin Zhang, Kevin Yarema & An Xu. 2017. Biological Effects of Static Magnetic Fields. Biological Effects of Static Magnetic Fields
81
131
.
Aleksandra Maziarz, Beata Kocan, Mariusz Bester, Sylwia Budzik, Marian Cholewa, Takahiro Ochiya & Agnieszka Banas. (2016) How electromagnetic fields can influence adult stem cells: positive and negative impacts. Stem Cell Research & Therapy 7:1.
Crossref
Crossref
Bahar Bilgen & Sedat Odabas. 2016. Advanced Surfaces for Stem Cell Research. Advanced Surfaces for Stem Cell Research
45
65
.
Marzie Moraveji, Nooshin Haghighipour, Hamid Keshvari, Tannaz Nourizadeh Abbariki, Mohammad Ali Shokrgozar & Amir Amanzadeh. (2016) Effect of Extremely Low Frequency Electromagnetic Field on MAP2 and Nestin Gene Expression of Hair Follicle Dermal Papilla Cells. The International Journal of Artificial Organs 39:6, pages 294-299.
Crossref
Crossref
Sara Hassanpour Tamrin, Fatemeh Sadat Majedi, Mahdi Tondar, Amir Sanati-Nezhad & Mohammad Mahdi Hasani-Sadrabadi. 2016. Reviews of Physiology, Biochemistry and Pharmacology, Vol. 171. Reviews of Physiology, Biochemistry and Pharmacology, Vol. 171
63
97
.
Carly A. Buckner, Alison L. Buckner, Stan A. Koren, Michael A. Persinger & Robert M. Lafrenie. (2015) Inhibition of Cancer Cell Growth by Exposure to a Specific Time-Varying Electromagnetic Field Involves T-Type Calcium Channels. PLOS ONE 10:4, pages e0124136.
Crossref
Crossref
Guang-Zhou An, Hui Xu, Yan Zhou, Le Du, Xia Miao, Da-Peng Jiang, Kang-Chu Li, Guo-Zhen Guo, Chen Zhang & Gui-Rong Ding. (2015) Effects of Long-Term 50Hz Power-Line Frequency Electromagnetic Field on Cell Behavior in Balb/c 3T3 Cells. PLOS ONE 10:2, pages e0117672.
Crossref
Crossref
Dillip Kumar Bishi, Soma Guhathakurta, Jayarama Reddy Venugopal, Kotturathu Mammen Cherian & Seeram Ramakrishna. (2014) Low frequency magnetic force augments hepatic differentiation of mesenchymal stem cells on a biomagnetic nanofibrous scaffold. Journal of Materials Science: Materials in Medicine 25:11, pages 2579-2589.
Crossref
Crossref
Dejing Shi, Chunbo Zhu, Rengui Lu, Shitong Mao & Yanhua Qi. (2014) Intermediate frequency magnetic field generated by a wireless power transmission device does not cause genotoxicity in vitro. Bioelectromagnetics 35:7, pages 512-518.
Crossref
Crossref
Ming-Yu Song, Ji-Zhe Yu, Dong-Ming Zhao, Sheng Wei, Yang Liu, Yue-Ming Hu, Wen-Chun Zhao, Yong Yang & Hua Wu. (2013) The Time-Dependent Manner of Sinusoidal Electromagnetic Fields on Rat Bone Marrow Mesenchymal Stem Cells Proliferation, Differentiation, and Mineralization. Cell Biochemistry and Biophysics 69:1, pages 47-54.
Crossref
Crossref
Ezio CorbelliniMonica CorbelliniOrazio LicciardelloFrancesco Marotta. (2014) Modulating Biological Events by Biophysics: An Innovative Molecular Methodology Using Ion Cyclotron Resonance—A Pilot Study. Rejuvenation Research 17:2, pages 188-191.
Crossref
Crossref
Aaron W. James. (2013) Review of Signaling Pathways Governing MSC Osteogenic and Adipogenic Differentiation. Scientifica 2013, pages 1-17.
Crossref
Crossref
Kanwal Haneef, Nermine Lila, Samira Benadda, Fabien Legrand, Alain Carpentier & Juan C. Chachques. (2018) Development of Bioartificial Myocardium by Electrostimulation of 3D Collagen Scaffolds Seeded with Stem Cells. Heart International 7:2, pages hi.2012.e14.
Crossref
Crossref
Yeon Hee HwangHo Sun SongHee Rae KimMyoung Soo KoJae Min JeongYong Ho KimJeong Soo RyuUy Dong SohnYoon-Myoung GimmSung Ho MyungSang Soo Sim. (2011)
Intracellular Ca
2+
Mobilization and Beta-hexosaminidase Release Are Not Influenced by 60 Hz-electromagnetic Fields (EMF) in RBL 2H3 Cells
. The Korean Journal of Physiology and Pharmacology 15:5, pages 313.
Crossref
Crossref