Gas in Scattering Media Absorption Spectroscopy

S. Svanberg
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引用次数: 3

Abstract

Gas in scattering media absorption spectroscopy (GASMAS) is a new variety of tunable diode laser spectroscopy (TDLS). It combines concepts from atmospheric trace-gas monitoring with those pertinent to biological tissue optics. The former field deals with high-resolution spectroscopy in nonscattering media, whereas the latter area is characterized by broad absorption structures in strongly scattering media. GASMAS provides novel applications in, e.g. the material science and biophotonics fields. The absorptive imprints of free gases inside pores or cavities in surrounding solid or liquid matter are typically many orders of magnitude narrower than those of the host material, a fact that is critically utilized. The gas signals are detected in the weak, multiply scattered light emerging from the illuminated sample. Wavelength-modulation and phase-sensitive detection techniques are employed, typically in connection with single-mode CW lasers. Any gas with useful absorption at wavelengths where the host material does not absorb strongly can be detected. For biological tissue, containing liquid water and blood, this limits the useful region to the “tissue optical window” –650–1400 nm – where, however, the interesting gases oxygen and water vapor absorb at around 760 and 950 nm, respectively. This limitation does not pertain to other materials, particularly not to those that do not contain liquid water. GASMAS experiments, which relate to basic physics, include studies of nanoporous ceramics, where wall collisions influence the line shape and provide information on pore-size distribution. A small piece of strongly scattering ceramic can serve as an alignment-free multipass cell with effective path length hundreds of times longer than the physical dimension. Porosity and gas transport studies in construction materials such as polystyrene foams, wood, ceramics, and paper are examples of applications in the material science field. The technique is further very powerful for studying gas in the human body and products that humans eat, such as packaged foods, fruits, and pharmaceutical preparations. A key aspect of food packaging is to prevent oxygen to influence the food. Frequently, modified atmospheres with nitrogen or carbon dioxide as filling gases are used. Applications include monitoring the performance of packaging machines and measurements of the product on the shelf. Porosity in pharmaceutical tablets is important to determine, as it has bearing on controlled release. Following initial work on healthy volunteers, a clinical trial concerning human sinus cavities has been performed. Gas filling and composition can be used as a diagnostic tool in connection with sinusitis, a very common disorder, also related to the problem with heavy overprescription of antibiotics and associated growing bacterial resistance. Following realistic phantom studies, it was shown that it is possible to detect gas in the lungs and intestines of a newborn baby, which could be of considerable interest for future care of prematurely born children. Gas diffusion and transport can be dynamically studied in response to an abrupt change in gas composition in medicine as well as in material science. The GASMAS technique is fully nonintrusive and nondestructive.
散射介质中的气体吸收光谱学
气体在散射介质中的吸收光谱(GASMAS)是一种新型的可调谐二极管激光光谱(TDLS)。它结合了大气痕量气体监测与生物组织光学相关的概念。前一个领域涉及非散射介质中的高分辨率光谱,而后一个领域的特点是在强散射介质中广泛的吸收结构。GASMAS在材料科学和生物光子学等领域提供了新的应用。周围固体或液体物质的孔隙或空腔内的自由气体的吸收印记通常比宿主材料的吸收印记窄许多个数量级,这是一个关键的事实。气体信号是在从被照亮的样品中产生的微弱的、多重散射光中检测到的。波长调制和相敏检测技术被采用,通常用于单模连续波激光器。可以检测到在宿主物质不强烈吸收的波长上有有用吸收的任何气体。对于含有液态水和血液的生物组织,这将有用的区域限制在“组织光学窗口”- 650 - 1400nm -然而,有趣的气体氧气和水蒸气分别在760和950 nm左右吸收。这一限制不适用于其他材料,特别是不含液态水的材料。GASMAS实验涉及基础物理,包括纳米多孔陶瓷的研究,其中壁碰撞影响线的形状并提供孔尺寸分布的信息。一小块强散射陶瓷可以作为无对准多通单元,其有效路径长度是物理尺寸的数百倍。在聚苯乙烯泡沫、木材、陶瓷和纸张等建筑材料中的孔隙率和气体输运研究是材料科学领域应用的例子。这项技术在研究人体气体和人类食用的产品(如包装食品、水果和药物制剂)方面也非常强大。食品包装的一个关键方面是防止氧气影响食品。通常,用氮气或二氧化碳作为填充气体来修饰大气。应用包括监控包装机器的性能和货架上产品的测量。测定片剂的孔隙度是很重要的,因为它关系到控释。在健康志愿者的初步工作之后,一项关于人类窦腔的临床试验已经进行。气体填充和成分可作为鼻窦炎的诊断工具,鼻窦炎是一种非常常见的疾病,也与抗生素的严重过度处方和相关的细菌耐药性增长有关。经过逼真的幻影研究,研究人员表明,在新生儿的肺部和肠道中检测气体是可能的,这可能对未来早产儿的护理有相当大的兴趣。在医学和材料科学中,气体的扩散和传输可以动态地研究,以响应气体成分的突然变化。GASMAS技术是完全非侵入性和非破坏性的。
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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