Structural studies on stabilized microbubbles: development of a novel contrast agent for diagnostic ultrasound

M.A Wheatley, S Singhal
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引用次数: 36

Abstract

Ultrasound is a noninvasive tool with which the physician can gain insight into the state of the internal organs of the body. A contrast agent is a substance which, when injected into the body improves the resolution of an image. The use of diagnostic ultrasound is limited without development of such an agent. This paper describes the development of a new class of contrast agent. The agent consists of microbubbles generated in a solution by sonication, and stabilized by a layer of nonionic surfactant molecules. A single surfactant type alone does not produce stable bubbles, and only certain combinations of surfactants, one with a hydrophile-lipophile balance (HLB) greater than 10.5 and the other with an HLB less than 9, are successful. An agent prepared from Span60® and Tween80® is described in detail. A Coulter analysis revealed that 90% of the bubbles were less than 10 μm in diameter. This is essential if the agent is to pass the pulmonary capillary bed. B-mode imaging of a sample of microbubbles indicated that these bubbles were highly echogenic (that is they produced a strong contrast). A Langmuir trough study of the molecular arrangement of the surfactant molecules inside the microbubble skin suggested that there are 1.7 molecules of Span to each Tween molecule. Detailed analysis of the pressure-area curves and area per molecule data lead to the hypothesis that the correct proportion of Span molecules can substantially reduce the head group repulsion found in the all-Tween situation, and this results in the generation of stable microbubbles. A molecular arrangement of these surfactant molecules around the microbubble is proposed.

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稳定微泡的结构研究:新型超声诊断造影剂的研制
超声波是一种非侵入性的工具,医生可以通过它来了解身体内部器官的状态。造影剂是一种物质,当注射到体内时,可以提高图像的分辨率。诊断超声的使用是有限的,没有这样一种试剂的发展。本文介绍了一种新型造影剂的研制。该试剂由超声在溶液中产生的微泡组成,并由一层非离子表面活性剂分子稳定。单独一种表面活性剂不能产生稳定的气泡,只有某些表面活性剂的组合,即一种亲水-亲脂平衡(HLB)大于10.5,另一种HLB小于9,才能成功。详细介绍了一种由Span60®和Tween80®制备的助剂。Coulter分析表明,90%的气泡直径小于10 μm。如果药物要通过肺毛细血管床,这是必不可少的。微气泡样本的b型成像显示这些气泡具有高回声(即它们产生强烈的对比)。Langmuir槽对微泡皮肤表面活性剂分子的分子排列进行了研究,发现每个Tween分子对应1.7个Span分子。通过对压力-面积曲线和每分子面积数据的详细分析,我们可以得出这样的假设:正确的Span分子比例可以大大降低all-Tween情况下的头基斥力,从而产生稳定的微泡。提出了这些表面活性剂分子在微泡周围的分子排列方式。
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