Garcia-Contreras L, Fiegel J, Telko M J, Elbert K, Hawi A, Thomas M, VerBerkmoes J, Germishuizen W A, Fourie P B, Hickey A J, Edwards D
University of North Carolina, Chapel Hill, NC 27599-7360, USA.
Antimicrob Agents Chemother. 2007 Aug;51(8):2830-6. doi: 10.1128/AAC.01164-06. Epub 2007 May 21.
Capreomycin is used for the treatment of multidrug-resistant tuberculosis (MDR-TB), but it is limited therapeutically by its severe side effects. The objectives of the present studies were (i) to design low-density porous capreomycin sulfate particles for efficient pulmonary delivery to improve local and systemic drug bioavailability and capacity to reduce the bacillary load in the lungs in a manner similar to that achieved with intramuscular injections; (ii) to determine pharmacokinetic parameters after pulmonary administration of these capreomycin particles; and (iii) to evaluate the efficacy of these particles in treating animals in a small-aerosol-inoculum guinea pig model of TB. Capreomycin particles were manufactured by spray drying and characterized in terms of size and drug content. Pharmacokinetic parameters were determined by noncompartmental methods with healthy guinea pigs after administration of capreomycin particles by insufflation. The efficacy of the particles was evaluated by histopathological analysis and in terms of wet organ weight and bacterial burden in TB-infected animals. Lungs of animals receiving a 14.5-mg/kg dose of capreomycin particles showed significantly lower wet weights and smaller bacterial burdens than those of animals receiving any other treatment. These results were supported by histopathological analysis. The feasibility of inhaling capreomycin in a novel powder form, with the ultimate objective of the treatment of MDR-TB, is demonstrated by pharmacokinetic and pharmacodynamic studies with guinea pigs. If applied to humans with MDR-TB, such a therapeutic approach might simplify drug delivery by eliminating injections and might reduce adverse effects through lowering the dose.
卷曲霉素用于治疗耐多药结核病(MDR-TB),但其严重的副作用限制了其治疗效果。本研究的目的是:(i)设计低密度多孔硫酸卷曲霉素颗粒,以实现高效肺部给药,提高局部和全身药物生物利用度,并降低肺部细菌载量,其效果类似于肌肉注射;(ii)确定肺部给药这些卷曲霉素颗粒后的药代动力学参数;(iii)在小型气溶胶接种豚鼠结核病模型中评估这些颗粒治疗动物的疗效。通过喷雾干燥制备卷曲霉素颗粒,并对其大小和药物含量进行表征。通过非房室方法在健康豚鼠经吹入法给予卷曲霉素颗粒后测定药代动力学参数。通过组织病理学分析以及感染结核病动物的湿器官重量和细菌负荷评估颗粒的疗效。接受14.5mg/kg剂量卷曲霉素颗粒的动物的肺湿重和细菌负荷明显低于接受其他任何治疗的动物。组织病理学分析支持了这些结果。豚鼠的药代动力学和药效学研究证明了吸入新型粉末形式卷曲霉素治疗耐多药结核病的可行性。如果应用于耐多药结核病患者,这种治疗方法可能通过消除注射来简化给药,并通过降低剂量来减少不良反应。