共查询到19条相似文献,搜索用时 140 毫秒
1.
磁性多孔聚苯乙烯微球的制备 总被引:2,自引:0,他引:2
在磁流体存在的情况下,采用改进了的乳液聚合法合成了具有磁核的微米级高分子聚苯乙烯微球。以该微球为种子,采用分散聚合法,以乙二醇/水为分散介质、聚乙二醇为分散剂、甲苯为制孔剂,进行苯乙烯-丙烯酸-二乙烯苯的三元共聚物的合成,最终合成出粒径分布均匀、磁响应性强的磁性多孔聚苯乙烯微球。 相似文献
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用沉积表面反应法制备了以聚苯乙烯为核、Mn-Fe氧化物为壳的磁性核-壳微球. 考察了锰含量对核-壳球磁性的影响,分别采用烧结法和溶剂萃取法去除核-壳球内的聚苯乙烯以制取中空微球. 讨论了烧结温度与所形成的中空微球比表面积的关系,考察了溶剂萃取法去除聚苯乙烯的效果,比较了两者所形成的中空微球的性能. 结果表明,烧结法所得微球性能优于溶剂萃取法所得微球. 探讨了烧结法形成中空磁性球的最佳条件,在400℃下煅烧核-壳微球可以得到饱和磁化强度为68.66 emu/g、比表面积为27.8438 m2/g的含锰铁氧化物磁性中空微球. 相似文献
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P(St-GMA-DVB)/Fe3O4高分子磁性微球的合成与表征 总被引:1,自引:0,他引:1
以FeCl3×6H2O和FeCl2×4H2O为原料,采用化学共沉淀法制备了Fe3O4油基磁流体,设计的合成工艺克服了合成磁流体过程中Fe3O4磁性粒子易团聚的缺点,合成了具有很好分散性和稳定性的磁流体,比饱和磁化强度达72.60 emu/g. 采用悬浮聚合方法合成了聚苯乙烯-甲基丙烯酸缩水甘油酯-二乙烯基苯[P(St-GMA-DVB)]高分子磁性微球,搅拌转速对磁性微球粒径影响大,磁性微球粒径在55~300 mm范围内,外形为具有单分散性的球形,表面环氧基团含量达17 mmol/g. 相似文献
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为了制备一种以四氧化三铁磁性纳米粒子为壳、聚苯乙烯为核的新型高分子功能材料,并有望应用于磁稳定流化床反应器,采用悬浮聚合法制备了四氧化三铁纳米粒子包覆聚苯乙烯的磁性微球。运用扫描电镜(SEM)、红外光谱(FT-IR)、振动样品磁强计(VSM)、热失重(TGA)等测试手段,分析并表征了磁性聚苯乙烯微球的形貌特征、粒径、磁学性能及四氧化三铁包覆量。实验结果表明,所得磁性聚苯乙烯粒子为球状微球,粒径为150~200 μm且分布较窄;磁性聚苯乙烯微球的四氧化三铁包覆量达到7.81%(质量分数),最高饱和磁化强度为3.97 A·m2/kg。 相似文献
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考察了核壳式表面功能化磁性聚苯乙烯纳米微球的可控制备工艺。采用紫外可见吸收光谱、透射电子显微镜、原子力显微镜及在不同溶剂中的分散性实验,对表面羧基化的磁性聚苯乙烯纳米微球的结构与形态进行了表征。结果表明,改变外加晶核Fe2O3纳米颗粒数目,可有效实现磁性聚苯乙烯纳米微球的尺寸可控。 相似文献
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荧光磁性双功能Fe3O4@PHEMA-Tb微球的制备及其蛋白固定化 总被引:1,自引:0,他引:1
以甲基丙烯酸-2-羟基乙酯为单体,N,N¢-亚甲基双丙烯酰胺为交联剂,采用光化学方法在Fe3O4磁性液体中制备了磁性聚甲基丙烯酸-2-羟基乙酯微球,合成了含有稀土元素Tb的荧光磁性高分子微球,以牛血清白蛋白为模型对微球固定释放蛋白能力进行了研究,用VSM, PCS, FT-IR, TG-DTA, SEM, FS, UV-Vis等技术对微球的性能进行了表征. 结果表明,荧光磁性高分子微球粒径为29.6 nm,比饱和磁化强度为40.1 emu/g,变异系数为3.7%,具有超顺磁性荧光性,分散性好,呈圆球形,对蛋白的装载率和包封率分别为6.5%和74.7%,pH越低蛋白释放率越高. 相似文献
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以六水合三氯化铁为铁源、乙二醇为溶剂和还原剂,采用溶剂热法制备了Fe3O4磁性粒子,同时以正硅酸乙酯为硅源,在碱性条件下对其进行修饰,从而得到具有较好稳定性和分散性的Fe3O4磁性粒子。又以β-环糊精和该修饰的Fe3O4磁性粒子为原料,环氧氯丙烷为交联剂,煤油为油相,采用反相乳液聚合法成功合成了β-环糊精磁性复合微球,并通过SEM、EDS、IR及XRD等方法对该微球进行了表征。结果表明:所合成的β-环糊精磁性复合微球表面光滑,形状比较圆整,粒径大小比较均匀,平均粒径约7μm,具有磁性且保留了β-环糊精的基本结构。 相似文献
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通过悬浮聚合技术合成了以聚苯乙烯为壁材、以石蜡为芯材的储能微球,研究了壁膜的选择及包覆程度。结果表明:聚苯乙烯很适合作为石蜡储能微球的壁膜,合成的石蜡聚苯乙烯微球包覆完整。 相似文献
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John P. Bullivant Shan Zhao Brad J. Willenberg Bettina Kozissnik Christopher D. Batich Jon Dobson 《International journal of molecular sciences》2013,14(9):17501-17510
Feraheme, is a recently FDA-cleared superparamagnetic iron oxide nanoparticle (SPION)-based MRI contrast agent that is also employed in the treatment of iron deficiency anemia. Feraheme nanoparticles have a hydrodynamic diameter of 30 nm and consist of iron oxide crystallites complexed with a low molecular weight, semi-synthetic carbohydrate. These features are attractive for other potential biomedical applications such as magnetic fluid hyperthermia (MFH), since the carboxylated polymer coating affords functionalization of the particle surface and the size allows for accumulation in highly vascularized tumors via the enhanced permeability and retention effect. This work presents morphological and magnetic characterization of Feraheme by transmission electron microscopy (TEM), Energy dispersive X-ray spectroscopy (EDX), and superconducting quantum interference device (SQUID) magnetometry. Additionally, the results of an initial evaluation of the suitability of Feraheme for MFH applications are described, and the data indicate the particles possess promising properties for this application. 相似文献
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Fe3O4 magnetic nanoparticles were prepared by the aqueous co-precipitation of FeCl3·6H2O and FeCl2·4H2O with addition of ammonium hydroxide. The conditions for the preparation of Fe3O4 magnetic nanoparticles were optimized, and Fe3O4 magnetic nanoparticles obtained were characterized systematically by means of transmission electron microscope (TEM), dynamic laser scattering analyzer (DLS) and X-ray diffraction (XRD). The results revealed that the magnetic nanoparticles were cubic shaped and dispersive, with narrow size distribution and average diameter of 11.4nm. It was found that the homogeneous variation of pH value in the solution via the control on the dropping rate of aqueous ammonia played a critical role in size distribution. The magnetic response of the product in the magnetic field was also analyzed and evaluated carefully. A 32.6 mT magnetic field which is produced by four ferromagnets was found to be sufficient to excite the dipole moments of 0.05g Fe3O4 powder 2cm far away from the ferromagnets. In conclusion, the Fe3O4 magnetic nanoparticles with excellent properties were competent for the magnetic carriers of targeted-drug in future application. 相似文献
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《分离科学与技术》2012,47(5):996-1020
Abstract The feasibility of a magnetic separator device for ex‐vivo blood detoxification was studied. This blood detoxification approach entails administering functionalized magnetic microspheres (FMMSs) into a patient's body by transdermal injection to capture and remove toxins from the blood using highly specific receptors attached to the surface of the FMMSs. These toxin‐loaded FMMSs are then removed from the body using extracorporeal blood circulation through a specially designed magnetic separator, based on high gradient magnetic separation principles. The performance of the magnetic separator, in terms of its collection efficiency (CE) of the FMMSs, was evaluated theoretically using a streamline analysis of a 2‐D model. The effects of blood velocity (1 to 20 cm/s), magnetic field strength (0.1 to 2.0 T), wire size (0.125 to 2.0 mm in radii), separator unit size at a fixed ratio of tube to wire diameter of one, tube length (2.0 to 20 cm), wire material (nickel, SS 430 and wairauite), and magnetic material comprising the FMMSs (iron, typical magnetite and weaker magnetite) on the CE were evaluated. Provided that the blood velocity was below 2 cm/s, CEs >80% could be attained under reasonable conditions, like when using FMMSs 400 nm in diameter and containing 60 wt% magnetite in a magnetic field of 0.5 T using a magnetic separator with 0.5 mm radii wire (at a fixed ratio of tube to wire diameter of close to one) that was 10 cm in length (same as the tube) and made of SS 430. CEs of between 30% and 80% could also be attained at blood velocities up to 20 cm/s without compromising the magnetic separator design. The magnetic separator performance improved by reducing the size of the unit with tubes and wires of equal radii, increasing the applied magnetic field strength, utilizing magnetic materials with the highest magnetizations, and increasing the length of the unit. Overall, the results from this study delineated the physically realistic conditions that make ex vivo blood detoxification possible with this magnetic separator device. 相似文献
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In this study, mono-sized anion-exchange microspheres with polyglycidylmethacrylate were engineered and processed to introduce magnetic granules by penetration–deposition approaches. The obtained magnetic microspheres showed a uniform particle diameter of 1.235 μm in average and a good spherical shape with a saturation magnetic intensity of 12.48 emu/g by VSM and 12% magnetite content by TGA. The magnetic microspheres showed no cytotoxicity when the concentration was below 10 μg/mg. The magnetic microspheres possess respective adsorption capacity for three proteins including Bovine albumin, Hemoglobin from bovine blood, and Cytochrome C. These magnetic microspheres are also potential biomaterials as targeting medicine carriers or protein separation carriers at low concentration. 相似文献
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《分离科学与技术》2012,47(3):355-363
A portable magnetic separator was proposed for in-vivo biomedical applications. In this prototype design, a matrix of alternating, parallel magnetizable wires, and biocompatible tubing is immersed into an externally applied magnetic field. The wires are magnetized and high magnetic fields as well as field gradients are created to trap blood-borne flowing magnetic nanospheres in the tube. In this paper, a parametric investigation was carried out to evaluate the capture efficiency of flowing magnetic nanospheres by a separator unit consisting of single tubing and four wires. The parameters include: mean blood velocity (1 to 20 cm/s); magnetic field strength (0.1 to 2.0 T); sphere size (500 nm to 1000 nm in radii); sphere magnetic material (iron, two types of magnetite) and magnetite content in the spheres (0.05 to 0.8 by weight); wire material (nickel, stainless steel 430, and Wairauite); wire length (2.0 to 20 cm); wire size (0.125 to 1.0 mm in radii); tubing size at a fixed ratio of tubing to wire diameter of unity. The results show that capture efficiencies of the spheres of well over 90% were achievable under reasonable human physiological conditions, provided that the mean blood velocities were below about 5.0 cm/s. The results also show that the magnetic separator performance could be improved by maximizing the applied magnetic field strength up to about 1.0 T and by reducing the size of the unit with tubing and wires of equal radii. The results help further optimize a prototype magnetic separator suitable for rapid sequestration of magnetic nanospheres from the human blood stream while accommodating necessary clinical boundary conditions. 相似文献
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磁性导向柔红霉素白蛋白微球的研究 总被引:7,自引:0,他引:7
:采用乳化交联技术将磁性超微粒子及柔红霉素包埋于白蛋白内 ,化学交联固化后制得柔红霉素磁性白蛋白微球。该微球呈球形 ,平均粒径为 2 32 μm ,大小分布均匀 ,在 0 0 5T磁场中具强磁响应性 ,在水中分散性好。磁性微球载药量为 11 2 6 % (mg/mg) ,包封率为 75 0 % ;临界相对湿度CRH =81 6 %。含药微球在体外 12h释放完全 ,具一定的缓释作用。体内外磁定位实验表明 ,DNR磁性白蛋白微球制剂可浓集于靶区。稳定性考察表明所制微球稳定性良好。 相似文献
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为了实现对钢铁行业微细颗粒的超低排放,提出磁性纤维提高对Fe基细颗粒物的捕集.基于计算流体力学-离散相模型CFD-DPM对比研究了传统纤维、磁性纤维直径对Fe基细颗粒捕集效率以及过滤阻力的影响.结果表明:当风速为0.10 m/s时,对于直径为35~45μm范围的纤维,直径的增大能够明显增加过滤阻力.对于粒径小于2.5 ... 相似文献
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以纳米纤维素(NCC)为组装模板,基于氢键的交替沉积自组装磁膜材料。X射线衍射(XRD)、透射电子显微镜(TEM)、扫描电子显微镜(SEM)和能量色散X射线光谱(EDX)分析结果表明,NCC负载纳米Fe3O4磁膜材料表面形貌和断面形貌规整,含有Fe3O4粒子为纳米级,且仅分布在NCC层。性能分析结果表明,NCC负载纳米Fe3O4磁膜材料为超顺磁性材料,与PVA膜相比,具有较好的紫外光阻隔性、较高的热稳定性和特殊的氧化降解能力;在Fe3O4固含量为1.1%时,磁性膜拉伸强度较PVA膜提高了17.0%。 相似文献