ABSTRACT
【Objective】 We combined the concept of traditional medicine with magnetic induction technology, originally brought up the research concept of magnetic hyperthermia to cure KOA, explored the mechanism and constructed a new treatment of KOA with modern medical features. 【Methods】 Through establishing a primary KOA model in rats and constructing ferrimagnetic vortex domain iron oxide nanorings (FVIOs) as a platform for highly efficient magnetic hyperthermia agent, the lesions of KOA were heated accurately under the low-intensity magnetic field. We confirmed the curative effect through the results of pain perception, histopathology, knee joint morphology and microscopic bone structure and the content of serum inflammatory factor, to study the therapeutic mechanism of magnetic hyperthermia for KOA. 【Results】 Compared with the model group, the recovery of mechanical pain threshold after magnetic hyperthermia improved by approximately 48.9%; the degree of hyperemia and edema of joint capsule and synovial tissue and the wear degree of joint cartilage surface, were significantly reduced; the Mankin and OARSI scores decreased by about 33% and 20%, respectively; the MicroCT results indicated that the degree of hardening of the subchondral bone also improved; the expression of inflammatory factors in the serum was reduced. 【Conclusion】 In this study, we utilized the FVIOs as a high-efficiency magnetic hyperthermia platform for the treatment of KOA. The efficacy of magnetic hyperthermia on KOA is clarified, and the mechanism is related to the inhibition of inflammatory factors.
ABSTRACT
Thermotherapy has become another important tumor treatment after surgery, radiotherapy, chemotherapy, and targeted treatment. Magnetic hyperthermia (MH) is a new type of hyperthermia, which has attracted widespread attention due to its advantages of non-invasiveness / minimal invasiveness, high efficiency and good tissue penetration. It provides a new option for the molecular level treatment of malignant tumors with high efficacy and low toxicity, which has become a new research direction of tumor treatment. Magnetic materials and suitable magnetic fields are needed to realize MH. Iron oxide nanoparticles (IONs) are widely studied as MH agents because of their high biocompatibility and heating ability. In this article, the research progress on magnetic iron oxide nanomaterials and MH combined with antitumor therapy based on magnetic nanoparticles were analyzed, and the potential application of MH in cancer treatment was reviewed.
ABSTRACT
ABSTRACT Objective: To evaluate the potential of magnetic hyperthermia using aminosilane-coated superparamagnetic iron oxide nanoparticles in glioblastoma tumor model. Methods: The aminosilane-coated superparamagnetic iron oxide nanoparticles were analyzed as to their stability in aqueous medium and their heating potential through specific absorption rate, when submitted to magnetic hyperthermia with different frequencies and intensities of alternating magnetic field. In magnetic hyperthermia in vitro assays, the C6 cells cultured and transduced with luciferase were analyzed by bioluminescence in the absence/presence of alternating magnetic field, and also with and without aminosilane-coated superparamagnetic iron oxide nanoparticles. In the in vivo study, the measurement of bioluminescence was performed 21 days after glioblastoma induction with C6 cells in rats. After 24 hours, the aminosilane-coated superparamagnetic iron oxide nanoparticles were implanted in animals, and magnetic hyperthermia was performed for 40 minutes, using the best conditions of frequency and intensity of alternating magnetic field tested in the in vitro study (the highest specific absorption rate value) and verified the difference of bioluminescence before and after magnetic hyperthermia. Results: The aminosilane-coated superparamagnetic iron oxide nanoparticles were stable, and their heating capacity increased along with higher frequency and intensity of alternating magnetic field. The magnetic hyperthermia application with 874kHz and 200 Gauss of alternating magnetic field determined the best value of specific absorption rate (194.917W/g). When these magnetic hyperthermia parameters were used in in vitro and in vivo analysis, resulted in cell death of 52.0% and 32.8%, respectively, detected by bioluminescence. Conclusion: The magnetic hyperthermia was promissing for the therapeutical process of glioblastoma tumors in animal model, using aminosilane-coated superparamagnetic iron oxide nanoparticles, which presented high specific absorption rate.
RESUMO Objetivo: Avaliar o potencial da técnica de magneto-hipertermia utilizando nanopartículas superparamagnéticas de óxido de ferro recobertas com aminosilana em modelo de tumores de glioblastoma. Métodos: As nanopartículas superparamagnéticas de óxido de ferro recobertas com aminosilana foram avaliadas quanto à sua estabilidade em meio aquoso e a seu potencial de aquecimento pela taxa de absorção específica, quando submetidas à magneto-hipertermia, com diferentes frequências e intensidades de campo magnético alternado. Nos ensaios de magneto-hipertermia in vitro, as células C6 cultivadas e transduzidas com luciferase foram avaliadas por bioluminescência na presença/ausência do campo magnético alternado, como também com e sem nanopartículas superparamagnéticas de óxido de ferro recobertas com aminosilana. No estudo in vivo, a medida de bioluminescência foi adquirida no 21º dia após indução do glioblastoma com células C6 nos ratos. Após 24 horas, as nanopartículas superparamagnéticas de óxido de ferro recobertas com aminosilana foram implantadas no animal, tendo sido realizada a magneto-hipertermia por 40 minutos, nas melhores condições de frequência e intensidade de campo magnético alternado testado no estudo in vitro (maior valor da taxa de absorção específica); foi verificada a diferença do bioluminescência antes e após a magneto-hipertermia. Resultados: As nanopartículas superparamagnéticas de óxido de ferro recobertas com aminosilana se mostraram estáveis, e sua capacidade de aquecimento aumentou com o incremento da frequência e da intensidade de campo magnético alternado. A aplicação da magneto-hipertermia, com 874kHz e 200 Gauss do campo magnético alternado, determinou o melhor valor da taxa de absorção específica (194,917W/g). Quando utilizados, estes parâmetros de magneto-hipertermia in vitro resultaram em morte celular de 52,0% e in vivo de 32,8% por bioluminescência. Conclusão: A técnica de magneto-hipertermia foi promissora para o processo terapêutico de tumores de glioblastoma no modelo animal utilizando as nanopartículas superparamagnéticas de óxido de ferro recobertas com aminosilana recobertas com aminosilana, que apresentaram alta taxa de absorção específica.