Effect of Laser Wavelengths on Drug Release with and without Gold Nanoshells and Magnetic Guidance on Uptake by Cancer Cells

Journal of Nanomedicine Research Pub Date : 2017-06-21 DOI:10.15406/JNMR.2017.06.00152

M. E. Khosroshahi, L. Ghazanfari, Z. Hassannejad

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引用次数: 3

Abstract

Nanomedicine deals with diagnosis, monitoring and treatment of diseases such as cancer and as well as control and understanding of biological systems. It is generally known that cancer treatment mainly relies on chemotherapy and radiotherapy where most anticancer drugs are essentially taken up by cells with high proliferative rate, a characteristic of cancer cells. However, normal tissue can also suffer from chemotherapeutic action, leading to undesirable side effects. To overcome these issues, strategies such as passive and active targeting have been proposed where they have a key role in nanomedicine for example in innovative controlled drug delivery and release systems that increase the bioavailability and concentration of anticancer drugs at target site [1,2]. Nanomaterials with special designs are frequently used as drug delivery systems to develop highly selective and effective diagnostic and therapeutic modalities [3,4]. Interestingly, external stimuli including electrical and magnetic fields can be utilized to suitably trigger the drug-loaded carriers to release the drug content in a controlled manner [5].

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激光波长对带金纳米壳和不带金纳米壳的药物释放的影响以及磁导对癌细胞摄取的影响

纳米医学涉及癌症等疾病的诊断、监测和治疗，以及对生物系统的控制和理解。众所周知，癌症的治疗主要依赖于化疗和放疗，而大多数抗癌药物本质上都是由具有高增殖率的细胞吸收的，这是癌细胞的一个特点。然而，正常组织也会受到化疗作用的影响，导致不良的副作用。为了克服这些问题，已经提出了被动和主动靶向等策略，它们在纳米医学中发挥关键作用，例如在创新的受控药物输送和释放系统中，这些系统可以提高靶向部位抗癌药物的生物利用度和浓度[1,2]。特殊设计的纳米材料经常被用作药物输送系统，以开发高选择性和有效的诊断和治疗方式[3,4]。有趣的是，可以利用包括电场和磁场在内的外部刺激来适当地触发载药载体以受控方式释放药物内容物[5]。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Nanomedicine Research

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