光学相干层析成像技术对关节软骨组织解剖分层表现对照研究

光学相干层析成像技术是一种高分辨率、非创伤性成像技术,它能够利用近红外光产生软骨组织的解析图像.实验的研究目的是验证光学相干层析成像技术对软骨组织解剖分层结构的成像能力.以猪膝关节软骨为样本,选择OCT检测的软骨区域运用解剖学方法获得组织切片,显微镜下观察.调查软骨OCT成像与组织学成像的相关性.结果显示OCT所测得的所有软骨的厚度值与切片显微镜结果一致,差异无显著意义 （P〉0.05）.光学相干层析成像系统能够呈现软骨组织解剖分层,该技术在软骨检测和临床关节病变诊断方面具有应用前景.     

光学相干断层成像在临床医学中的应用

光学相干断层成像(OCT)是一种基于弱相干光学断层成像技术,可以对生物组织活体断层成像,是继计算机X射线摄影(CR)和数字X射线摄影(DR)、超声、电子计算机断层扫描(CT)、磁共振成像(MRI)之后又一新的生物组织成像方法。OCT在眼科、皮肤科、心血管科、肿瘤科、骨科、口腔科、妇科等对组织病变的早期光学诊断和实时动态监测方面具有广泛的应用及重要的临床价值。本文就OCT的基本原理、研究现状、主要的临床应用和应用过程中存在的问题进行综述并展望未来相关的发展趋势。     

位相分辨偏振灵敏光学相干层析术:组织双折射特性的成像与定量分析

我们研制了一种基于光纤的位相分辨偏振灵敏光学相干层析成像系统。该系统中的偏振状态控制设量在参考臂而非光源臂上,因而使得光抵达样品的传输效率大大提高。鉴于光源的部分偏振性,入射于样品上的光含有任意偏振状态的分量,通过对参考光偏振状态的调制,就可相干地提取对应于入射光四种正交偏振状态并经样品后向散射的光信号。基于斯托克斯矢量夹角在无损光纤系统传输的变换不变性,我们能利用测量臂中光信号的斯托克斯参数来确定双折射样品深度分辨的位相延迟信息。利用所研制的偏振灵敏光学相干层析成像系统,不仅确认了韧带和软骨的双折射性质,而且定量分析了不同条件下韧带的双折射变化．研究结果表明：韧带松弛可使其双折射特性明显减弱,而韧带经拉伸后,其双折射特性的变化却不明显。     

光学技术在早期龋齿检测中的应用

介绍了光学技术在口腔医学早期龋齿无损检测领域的应用,包括基于牙齿自体荧光效应的定量光导荧光技术和激光龋齿检测技术;基于光散射效应的数字化显影光纤透照术,以及基于牙釉质双折射效应的偏振敏感光学相干断层术和偏振拉曼光谱技术.详细介绍了各种光学方法应用于龋齿检测的基本原理、实验方案和研究现状,并对不同的光学方法进行比较.最后,提出基于频域荧光寿命成像的早期龋齿检测方法,并对该方案的技术路线进行了介绍.     

基于自适应光学的视网膜单细胞光学相干层析成像技术

介绍了一种基于CCD相机的并行光学相干层析成像技术,将所建立的层析成像系统和自适应光学视网膜相机结合。利用一维光学相干层析系统对人眼视网膜进行追踪并控制相干门在视网膜内的位置,利用基于CCD相机的二维光学相干层析成像系统记录视网膜的干涉图像。用眼模型和牛眼视网膜组织对系统进行了测试,通过将4幅干涉图像的获取时间控制在7 ms以内来减少视网膜运动对成像的影响;系统的轴向点扩展函数和灵敏度分别达到10 μm和76 dB。实验结果表明,所建立的基于自适应光学的视网膜光学相干层析成像系统的空间分辨率和灵敏度远远高于其它基于自适应光学的视网膜成像技术。     

图形处理器在实时光学相干断层成像中的应用

光学相干断层成像(optical coherence tomography,OCT)技术在成像过程中具有极大的数据量和计算量,传统的基于中央处理器(central processing unit,CPU)的计算平台难以满足OCT实时成像的需求。图形处理器(graphics processing unit,GPU)在通用计算方面具有强大的并行处理能力和数值计算能力,可以突破OCT实时成像的瓶颈。本文对GPU做了简要介绍并阐述了GPU在OCT实时成像及功能成像中的应用及研究进展。     

去角质化的光学相干成像检测

皮肤角质(stratum corneum,SC)在维持皮肤结构完整和屏障功能中发挥重要作用,其无损检测很有意义。本文使用鼠耳模型,利用时域光学相干断层成像(TD-OCT)技术对丙酮去角质化的过程进行了检测。结果显示TD-OCT成像方法可测量角质层厚度、对去角质化做定性分析,在皮肤结构和屏障功能的无损检测中有一定临床价值。     

生物光学成像专刊征文通知

本专刊主要由有关生物组织光学成像方面的邀稿和投稿组成。近年来 ,在高散射介质中 (尤其在生物组织中 )光输运问题被越来越广泛和深入的研究。这些研究可以开发一些新的无损而又廉价的医学光学成像技术。光学成像因其可以提供生理学功能型的医学影像 ,而引起学术界广泛的关注。光学成像主要包括漫射光断层成像、相干光断层成像 ( OCT)、早到光子技术、超声调制技术、磁光调制技术、偏振调制技术等等方面。在这些技术中 ,相干光断层成像具有较高的空间分辨率 ,技术相对比较成熟 ,但其检测深度有限。漫射光断层成像的空间分辨率是比较低的 …     

生物光学成像专题征文通知

本专刊主要由有关生物组织光学成像方面的邀稿和投稿组成。近年来 ,在高散射介质中 (尤其在生物组织中 )光输运问题被越来越广泛和深入的研究。这些研究可以开发一些新的无损而又廉价的医学光学成像技术。光学成像因其可以提供生理学功能型的医学影像 ,而引起学术界广泛的关注。光学成像主要包括漫射光断层成像、相干光断层成像 ( OCT)、早到光子技术、超声调制技术、磁光调制技术、偏振调制技术等等方面。在这些技术中 ,相干光断层成像具有较高的空间分辨率 ,技术相对比较成熟 ,但其检测深度有限。漫射光断层成像的空间分辨率是比较低的 …     

人手部皮下微循环特性随深度变化的研究

本研究使用手持式扫频光学相干层析(SSOCT)系统分别在人左手无名指指甲上方、无名指指腹和手掌大拇指根部选取3 mm×3 mm区域进行了在体成像,使用指数补偿方法还原血流信息,获取不同深度的血流正面光学断层图像(en face图像),从血管灌注密度(PD)、血管直径(VD)两个方面分析了微循环随深度的变化特性。试验结果证明,在上述三个成像位置中,随着成像深度的增加,血管PD与血管VD均增大,血流信息的丰富程度增加,但同时en face图像的清晰度有所下降。其中左掌大拇指根部微血管最为细密,血流信息较为丰富,比较适宜作为微循环疾病诊断研究的成像部位。分层投影结果显示,左手无名指指甲上方部位在成像深度较浅(220～660μm)时,血管PD明显小于其他两个成像部位,说明此处在该范围内血流信息丰富程度不够。本文测量了随深度变化的手部血流几何学特征,验证了光学相干层析(OCT)技术基于手部皮下微循环光学断层图像进行疾病诊断的可行性。许多微循环疾病早期就已经产生了微血管病变,因此对这种微循环变化的探测在疾病的早期诊断方面具有临床指导意义。     

Specimen preparation and quantification of collagen birefringence in unstained sections of articular cartilage using image analysis and polarizing light microscopy

To establish an optimal method for analysis of the collagen structures from unstained tissue sections, a computerized image analysis system using a charge coupled device camera coupled to a polarizing light microscope was used. Retardation values of birefringence, which are proportional to the content and fibril orientation of collagen in the extracellular matrix of articular cartilage, were determined from sections prepared in different ways. In the superficial zone of articular cartilage, the highest retardation values were recorded from sections cut parallel to the so-called split lines indicating the anisotropic arrangement of collagen. Complete digestion of glycosaminoglycans reduced the retardation value by approximately 6.0%, suggesting a minor, but not insignificant, contribution of glycosaminoglycans to the birefringence of the matrix. The use of a mounting medium with a refractive index close to that of the collagen (e.g. DPX) increased the specificity of the method, since the optical anisotropy of collagen derives predominantly from the intrinsic (structural) birefringence. In conclusion, analysis of unstained sections after careful removal of paraffin and glycosaminoglycans from the tissues provides a sensitive and rapid quantitative assessment of oriented collagen structures in articular cartilage     

Decreased collagen stability as a response to the loss of structural integrity of thyroid cartilage

The thermal behavior, birefringence properties, and the biochemical composition of thyroid cartilage tissues have been studied. The hyaline cartilage, which was visualized as a quasi-isotropic medium, was composed of type II collagen, which did not denature at temperatures up to 100 degrees C. However, in hyaline cartilage digested by trypsin, the denaturation of collagen occured at 60 degrees C. Collagen fibers in the perichondrium were composed of type I and II collagen and formed a highly organized anisotropic structure (birefringence about 4.75 x 10(-3)) with a melting temperature of about 65 degrees C. The temperature of collagen denaturation in perichondrium in the whole system perichondrium-hyaline cartilage increased up to 75 degrees C, indicating the immobilization of perichondrium collagen by the extracellular matrix of the hyaline constituent.     

Decreased collagen thermal stability as a response to the loss of structural integrity of thyroid cartilage

The amino acid composition, thermal behavior and birefringence properties of thyroid cartilage tissues have been studied. A collagen component in perichondrium consists of type-I and type-II collagens whose fibers form a highly ordered anisotropic structure with a birefringence of 4.75 × 10^?3 and a melting (denaturation) temperature of 65°C. The hyaline constituent, which is visualized as a quasi-anisotropic medium, contains of only type-II collagen, which does not denature in intact tissues at temperatures up to 100°C. However, in tissues whose proteoglycane subsystem is damaged by trypsin, the denaturation of collagen takes place at 60°C. In the integral perichondrium-hyaline system, the temperature of collagen denaturation in the perichondrium reaches 75°C, which indicates the immobilization of collagen in this tissue by the extracellular matrix of the hyaline constituent.     

Video image processing greatly enhances contrast, quality, and speed in polarization-based microscopy

Video cameras with contrast and black level controls can yield polarized light and differential interference contrast microscope images with unprecedented image quality, resolution, and recording speed. The theoretical basis and practical aspects of video polarization and differential interference contrast microscopy are discussed and several applications in cell biology are illustrated. These include: birefringence of cortical structures and beating cilia in Stentor, birefringence of rotating flagella on a single bacterium, growth and morphogenesis of echinoderm skeletal spicules in culture, ciliary and electrical activity in a balancing organ of a nudibranch snail, and acrosomal reaction in activated sperm.     

Birefringence of Protein Solutions and Biological Systems. I

The quantitative interpretation of birefringence of biological structures such as muscle requires a knowledge of intrinsic birefringence of the components. The intrinsic birefringence of fibrous structures as determined by variation of solvent index is positive while the intrinsic birefringence of proteins in solution is negative as calculated by the Peterlin-Stuart theory. As a first step in clarifying this discrepancy the basis of the Peterlin-Stuart theory has been re-examined. The theory has been recalculated from the standpoint of light scattering and extended to particles whose length is not small compared to the wavelength. The birefringence of a system of particles possessing a shell with index different from the bulk solvent has been obtained in order to interpret measurements in mixed solvents.     

A comparative microscopic and ultrastructural study of perichondrial tissue in cartilage of Octopus vulgaris (Cephalopoda, Mollusca)

The microscopic and submicroscopic structures of perichondrial tissues in the head cartilages of Octopus vulgaris were studied by polarized light and transmission electron microscopy. The orbital cartilages possess a birefringent layer parallel to the surface of the cartilage; ultrastructurally, this layer, which may be considered perichondrial tissue, has the typical organisation of connective tissue but does not possess the stratification of collagen laminae found in vertebrate perichondria. Perichondrial extracellular matrix is clearly distinct from that of cartilage because its collagen fibrils are of a larger diameter than collagen fibrils from cartilage. In addition, perichondrial fibroblasts are characteristically located at the center of collagen fibers. In the cerebral cartilage, the perichondrium is absent or discontinuous in relation to complex interconnections between cartilage and connective fibres, muscle fibres, blood vessels and nerve. Distinctive cartilage-lining cells, rich in electron dense cytoplasmatic granules, are stratified either along the cartilage surface or along vessels and muscle fibres that penetrate within the cartilage. The perichondrium of cephalopod cartilage, whose structure varies according to the location and function of its skeletal segments, mimics that of vertebrate perichondrium, exemplifying the high level of tissue differentiation attained by cephalopods.     

Effect of Partial H2O-D2O Replacement on the Anisotropy of Transverse Proton Spin Relaxation in Bovine Articular Cartilage

Anisotropy of transverse proton spin relaxation in collagen-rich tissues like cartilage and tendon is a well-known phenomenon that manifests itself as the “magic-angle” effect in magnetic resonance images of these tissues. It is usually attributed to the non-zero averaging of intra-molecular dipolar interactions in water molecules bound to oriented collagen fibers. One way to manipulate the contributions of these interactions to spin relaxation is by partially replacing the water in the cartilage sample with deuterium oxide. It is known that dipolar interactions in deuterated solutions are weaker, resulting in a decrease in proton relaxation rates. In this work, we investigate the effects of deuteration on the longitudinal and the isotropic and anisotropic contributions to transverse relaxation of water protons in bovine articular cartilage. We demonstrate that the anisotropy of transverse proton spin relaxation in articular cartilage is independent of the degree of deuteration, bringing into question some of the assumptions currently held over the origins of relaxation anisotropy in oriented tissues.     

Reconstruction of a three-dimensional structure using cartilage regenerated from the perichondrium of rabbits

Human tissues such as those found in the ear, nose, eyelid, lip, and larynx have complicated and delicate three-dimensional structures, which are difficult to reconstruct and restore to normal function following damage by tumor, congenital disease, or trauma. We devised a new reconstructive technique for the lost tissues by using cartilage regenerated from the perichondrium. In 12 ears of 12 rabbits, the layer between the perichondrium and the cartilage was stripped off. The exposed cartilage was punched out in large amounts to resemble a flexible, honeycomb-like structure. Then, we sandwiched the rabbit ears with two thermoplastic plates, which maintained a structure of the anterior surface of the human ear for 8 weeks. Structural change was studied in all cases, and some parts of the remodeled tissue were studied pathologically. Out of 12 ears, 8 had a rigid structure with a shape like a human ear using regenerated cartilage from the perichondrium of rabbits, 2 were infected, and 2 had a decubitus ulcer on the conchal surface as a result of compression from the plate. This study suggests that the use of the cartilage regenerated from the perichondrium may lead to a successful treatment also in humans for a variety of three-dimensional structures that have been damaged.     

Preservation of elastic system fibers and of collagen molecular arrangement and stainability in an Egyptian mummy

The present findings show that both elastic system fibers and collagen markedly resisted change in tissues more than 2000 years old. The distribution of elastic fibers and elastic-related fibers (namely, oxytalan and elaunin fibers) in mummified tissues coincided with the observations made on the modern human tissues used as controls. The collagenous structures present in tissue sections obtained from the Egyptian mummy studied took on a deeply red colour when stained in the Picrosirius solution indicating that, as well as in the fresh controls, the basic groups in the collagen molecules were available for reacting with the strongly acidic dye Sirius Red. When viewed with polarized light, the collagen in the same tissue sections displayed an increased birefringence, which shows that the collagen molecules in mummified tissues maintain the oriented disposition which is typical of the modern human tissues used as controls. The methods employed have proved to be useful for the delineation of the elastic system fibers and of the collagenous scaffolding, which may be used as valuable landmarks in the study of the histoarchitecture of organs that have undergone considerable distortion.