Shaik M S, Ikediobi O, Turnage V D, McSween J, Kanikkannan N, Singh M
Division of Pharmaceutics, College of Pharmacy, Florida A&M University, Tallahassee 32307, USA.
J Pharm Pharmacol. 2001 May;53(5):617-27. doi: 10.1211/0022357011775947.
The carboxylic ionophore monensin was formulated into long-circulating nanoparticles with the help of polyethylene glycol/poly (DL-lactide-co-glycolide) diblock copolymers, in an attempt to enhance the cytotoxicity of a ricin-based immunotoxin, anti-My9, and anticancer drugs like adriamycin and tamoxifen. This study looked into various aspects involving the preparation (using a homogenizer and an EmulsiFlex homogenizer-extrusion device) and lyophilization of long-circulating monensin nanoparticles (LMNP) of particle size < 200 nm in diameter. The particle size of LMNP was reduced from 194 nm to 160 nm by passing the nanoparticles through an EmulsiFlex, before freeze-drying. There was a 4.8-83.7% increase in the particle size of LMNP after freeze-drying, which was dependent upon the manufacturing conditions such as use of the EmulsiFlex for size reduction before freeze-drying, the freezing method (rapid/slow) and the concentration of lyoprotectant (mannitol or trehalose) employed for freeze-drying. LMNP freeze-dried with 2.4% of trehalose showed minimal size change (< 9%) after freeze-drying. Further, the freezing method was found to have negligible effect on the particle size of LMNP freeze-dried with trehalose in comparison with mannitol. The entrapment efficiency of monensin in LMNP was found to be 14.2 +/- 0.3%. The LMNP were found to be spherical in shape and smooth in surface texture as observed by atomic force microscopy. In-vitro release of monensin from LMNP in phosphate buffered saline (PBS) pH 7.4 or PBS supplemented with 10% human serum indicated that there was an initial rapid release of about 40% in the first 8 h followed by a fairly slow release (about 20%) in the next 88 h. In-vivo studies conducted with Sprague-Dawley rats showed that 20% of monensin remained in circulation 4-8 h after the intravenous administration of LMNP. An in-vitro dye-based cytotoxicity assay (MTS/PMS method) showed that there was 500 times and 5 times potentiation of the cytotoxicity of anti-My9 immunotoxin by LMNP (5 x 10(-8) M of monensin) in HL-60 sensitive and resistant human tumour cell lines, respectively. Further, LMNP (5 x 10(-8) M of monensin) potentiated the cytotoxicity of adriamycin in MCF 7 and SW 620 cell lines by 100 fold and 10 fold, respectively, and that of tamoxifen by 44 fold in MCF 7 cell line as assessed by crystal violet dye uptake assay. Our results suggest that it is possible to prepare LMNP possessing appropriate particle size (< 200 nm), monensin content and in-vitro and in-vivo release characteristics with the help of a homogenizer and an EmulsiFlex homogenizer-extrusion device. LMNP can be freeze-dried with minimal increase in particle size by using a suitable concentration of a lyoprotectant like trehalose. Furthermore, LMNP could potentiate the cytotoxicity of immunotoxin, adriamycin and tamoxifen by 5-500 fold in-vitro, which will be further investigated in-vivo in a suitable animal model.
借助聚乙二醇/聚(DL-丙交酯-共-乙交酯)二嵌段共聚物,将羧酸离子载体莫能菌素制成了长循环纳米颗粒,旨在增强基于蓖麻毒素的免疫毒素抗My9以及阿霉素和他莫昔芬等抗癌药物的细胞毒性。本研究探讨了制备(使用均化器和EmulsiFlex均化器-挤压装置)和冻干直径小于200 nm的长循环莫能菌素纳米颗粒(LMNP)所涉及的各个方面。在冻干前,通过EmulsiFlex使纳米颗粒通过,LMNP的粒径从194 nm减小到160 nm。冻干后,LMNP的粒径增加了4.8%-83.7%,这取决于制造条件,如冻干前使用EmulsiFlex减小粒径、冷冻方法(快速/慢速)以及冻干所用冻干保护剂(甘露醇或海藻糖)的浓度。用2.4%海藻糖冻干的LMNP在冻干后粒径变化最小(<9%)。此外,与甘露醇相比,发现冷冻方法对用海藻糖冻干的LMNP的粒径影响可忽略不计。莫能菌素在LMNP中的包封率为14.2±0.3%。通过原子力显微镜观察发现,LMNP呈球形,表面质地光滑。在pH 7.4的磷酸盐缓冲盐水(PBS)或添加10%人血清的PBS中,莫能菌素从LMNP的体外释放表明,在最初8小时内约有40%的药物快速释放,随后在接下来的88小时内释放相当缓慢(约20%)。用Sprague-Dawley大鼠进行的体内研究表明,静脉注射LMNP后4-8小时,20%的莫能菌素仍在循环中。基于染料的体外细胞毒性试验(MTS/PMS法)表明,在HL-60敏感和耐药人肿瘤细胞系中,LMNP(5×10⁻⁸ M莫能菌素)分别使抗My9免疫毒素的细胞毒性增强了500倍和5倍。此外,通过结晶紫染料摄取试验评估,LMNP(5×10⁻⁸ M莫能菌素)在MCF 7和SW 620细胞系中分别使阿霉素的细胞毒性增强了100倍和10倍,在MCF 7细胞系中使他莫昔芬的细胞毒性增强了44倍。我们的结果表明,借助均化器和EmulsiFlex均化器-挤压装置,可以制备出具有合适粒径(<200 nm)、莫能菌素含量以及体外和体内释放特性的LMNP。通过使用合适浓度的海藻糖等冻干保护剂,LMNP冻干后粒径增加最小。此外,LMNP在体外可使免疫毒素、阿霉素和他莫昔芬的细胞毒性增强5-500倍,这将在合适的动物模型中进一步进行体内研究。
