{"title":"In silico full-angle high-dynamic range scattering of microscopic objects exploiting holotomography.","authors":"Seung Kyu Kang,Kyoohyun Kim,Jinsoo Jeong,Sunghee Hong,YongKeun Park,Jonghwa Shin","doi":"10.1364/boe.528698","DOIUrl":null,"url":null,"abstract":"Accurate optical characterization of microscopic objects is crucial in academic research, product development, and clinical diagnosis. We present a method for obtaining full and high-dynamic range, angle-resolved light scattering attributes of microparticles, enabling distinction of variations in both overall morphology and detailed internal structures. This method overcomes previous limitations in observable scattering angles and dynamic range of signals through computationally assisted three-dimensional holotomography. This advancement is significant for particles spanning tens of wavelengths, such as human erythrocytes, which have historically posed measurement challenges due to faint side-scattering signals indicative of their complex interiors. Our technique addresses three key challenges in optical side-scattering analysis: limited observational angular range, reliance on simplified computational models, and low signal-to-noise ratios in both experimental and computational evaluations. We incorporate three-dimensional tomographic complex refractive index data from Fourier-transform light scattering into a tailored finite-difference time-domain simulation space. This approach facilitates precise near-to-far-field transformations. The process yields complete full-angle scattering phase functions, crucial for particles like Plasmodium falciparum-parasitized erythrocytes, predominantly involved in forward scattering. The resultant scattering data exhibit an extreme dynamic range exceeding 100 dB at various incident angles of a He-Ne laser. These findings have the potential to develop point-of-care, cost-effective, and rapid malaria diagnostic tools, inspiring further clinical and research applications in microparticle scattering.","PeriodicalId":8969,"journal":{"name":"Biomedical optics express","volume":"14 1","pages":"5238-5250"},"PeriodicalIF":2.9000,"publicationDate":"2024-08-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Biomedical optics express","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1364/boe.528698","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"BIOCHEMICAL RESEARCH METHODS","Score":null,"Total":0}
引用次数: 0
Abstract
Accurate optical characterization of microscopic objects is crucial in academic research, product development, and clinical diagnosis. We present a method for obtaining full and high-dynamic range, angle-resolved light scattering attributes of microparticles, enabling distinction of variations in both overall morphology and detailed internal structures. This method overcomes previous limitations in observable scattering angles and dynamic range of signals through computationally assisted three-dimensional holotomography. This advancement is significant for particles spanning tens of wavelengths, such as human erythrocytes, which have historically posed measurement challenges due to faint side-scattering signals indicative of their complex interiors. Our technique addresses three key challenges in optical side-scattering analysis: limited observational angular range, reliance on simplified computational models, and low signal-to-noise ratios in both experimental and computational evaluations. We incorporate three-dimensional tomographic complex refractive index data from Fourier-transform light scattering into a tailored finite-difference time-domain simulation space. This approach facilitates precise near-to-far-field transformations. The process yields complete full-angle scattering phase functions, crucial for particles like Plasmodium falciparum-parasitized erythrocytes, predominantly involved in forward scattering. The resultant scattering data exhibit an extreme dynamic range exceeding 100 dB at various incident angles of a He-Ne laser. These findings have the potential to develop point-of-care, cost-effective, and rapid malaria diagnostic tools, inspiring further clinical and research applications in microparticle scattering.
对微观物体进行精确的光学表征对于学术研究、产品开发和临床诊断至关重要。我们提出了一种获取微颗粒的完整、高动态范围、角度分辨光散射属性的方法,从而能够区分整体形态和详细内部结构的变化。这种方法通过计算辅助三维全图成像克服了以往在可观测散射角和信号动态范围方面的限制。对于人类红细胞等波长跨度达数十个波长的颗粒来说,这一进步意义重大,因为这些颗粒内部结构复杂,会产生微弱的侧向散射信号,这在历史上曾给测量工作带来挑战。我们的技术解决了光学侧向散射分析中的三大难题:观测角度范围有限、依赖简化的计算模型以及实验和计算评估中的低信噪比。我们将傅立叶变换光散射的三维层析复折射率数据纳入定制的有限差分时域模拟空间。这种方法有助于进行精确的近场到远场转换。这一过程产生了完整的全角散射相位函数,这对恶性疟原虫寄生红细胞等主要参与前向散射的颗粒至关重要。在氦氖激光器的不同入射角度下,所得到的散射数据显示出超过 100 dB 的极限动态范围。这些发现有望开发出成本效益高、快速的疟疾床旁诊断工具,激发微粒子散射的进一步临床和研究应用。
期刊介绍:
The journal''s scope encompasses fundamental research, technology development, biomedical studies and clinical applications. BOEx focuses on the leading edge topics in the field, including:
Tissue optics and spectroscopy
Novel microscopies
Optical coherence tomography
Diffuse and fluorescence tomography
Photoacoustic and multimodal imaging
Molecular imaging and therapies
Nanophotonic biosensing
Optical biophysics/photobiology
Microfluidic optical devices
Vision research.