皮肤的光学模型

基于人体皮肤的组织结构,光在皮肤组织中的传输特性以及皮肤各层的组织光学参数,建立了正常皮肤的光学模型,介绍了该模型中的组织光学参数的确定方法。本文建立的皮肤组织光学模型及其方法,可应用于皮肤光学基础与临床的其它研究中。     

生物组织中有限束宽光吸收的蒙特卡罗模拟

用蒙特卡罗法模拟了有限束宽均匀分布和高斯分布光在生物组织中的传播,分析了生物组织的光学参数及光源特性对光吸收分子的影响,结果表明：只要有效光吸收系数增加,最大光吸收率就会增加,光的侧向传输能力主要依赖于光的有效散射,光束宽度增加,辐照范围加宽,高斯光束的吸收分布的梯度更大。     

光动力疗法过程中的光漂白特性

基于光动力过程中的光分布规律,研究了半无限大组织中组织光学特性和光分布对光漂白作用效果的影响.研究发现光漂白效果与组织的散射系数和吸收系数成反比;光漂白的有效作用深度是4.5 mm,最大作用深度是33 mm.研究所得结果不仅表明通过光分布研究光漂白的特性是一种有效的方法,而且对临床上设计合理的治疗法案具有重要的参考作用...     

用蒙特卡罗方法模拟光在多层组织中的吸收特性

在讨论目前新颖的组织功能成像打骂能性（例如光声成像）时,光子在组织中的吸收和散射特性是一个很重要的问题,鉴于这一点,本文利用一个多层模型研究了光子在皮肤,脂肪和肌肉组织中的吸收和散射特性,得到了在组织中某一深度处光子在一个平面上的吸收分布,以及在不同吸收系数和散射系数的情况下,光子的反射,吸收和透射几率,结果表明在经过多次散射后,大部分的光子被吸收,在本文的模型中只有7.3%的光子从表面反射（包括镜面反射和漫反射）,还讨论了不同光学参灵敏对参流分布的影响。     

光声成像及其在生物医学中的应用

光声成像是一种新近迅速发展起来、基于生物组织内部光学吸收差异、以超声作媒介的无损生物光子成像方法,它结合了纯光学成像的高对比度特性和纯超声成像的高穿透深度特性的优点,以超声探测器探测光声波代替光学成像中的光子检测,从原理上避开了光学散射的影响,可以提供高对比度和高分辨率的组织影像,为研究生物组织的结构形态、生理特征、代谢功能、病理特征等提供了重要手段,在生物医学临床诊断以及在体组织结构和功能成像领域具有广泛的应用前景.对光声成像技术的机理、光声成像技术和方法、光声图像重建算法以及光声成像在生物医学上的应用情况作一个简单介绍,希望有助于推动我国在该领域的科研和开发应用工作的迅速发展.     

基于光谱编码的血管内光声组分成像

光声成像突破了传统的光学成像和超声成像在生物组织成像领域的困境,该技术基于光声(Photoacoustic,PA)效应,脉冲激光激励下的生物组织产生超声信号,超声信号被接收后,通过反投影算法将其携带的时间信息和强度信息转化为能够反映生物组织吸收结构和分布的可视化图像。基于不同生物组织的光吸收差异,当激发光强度均匀且稳定时,光声成像反映的就是该物质对于该波长光的吸收特性。本文中,我们基于导管式的血管内光声断层扫描平台结合多波长激发的光声成像算法开发了基于光谱编码的血管内光声组分成像系统,实现了在离体血管斑块中脂质组分的定量成像,高分辨获得了脂质核心的大小形态和边界信息,表征了斑块内的脂质相对含量。     

光动力学疗法的单态氧剂量学研究进展

单态氧(1O2)是光动力学疗法(photodynamic therapy,PDT)过程中Ⅱ型光化学反应的主要细胞毒性物质.通过直接测量1O2发光强度预测PDT疗效已成为PDT剂量学研究的前沿热点,这种方法的最大优点在于能够克服现有其它剂量学方法中的光、光敏剂、氧分子,以及组织光学特性等因素之间的复杂相互影响,将PDT的...     

光动力治疗光源的研究新进展

光动力疗法(PDT)是一种联合利用治疗光源、光敏剂和氧分子,选择性治疗恶性肿瘤和良性疾病的精准靶向疗法。光源作为PDT治疗的关键要素之一,其发光波长、照光方式和剂量直接影响疗效。本文详细介绍了太阳光、近红外光、X射线、在体发光和发光二极管等5种PDT光源的研究新进展,并分析了这五种治疗光源在生物组织穿透深度上的不同特性以及所存在的不足。随后,重点讨论了以提高PDT治疗精度为目标的体表照光和体内照光等两种个性化照光模式。研发操作简便、价格低廉、性能优异的新型PDT光源是未来的发展方向。     

光刺激参数控制器

本文介绍一种能准确而迅速改变光刺激器光学参数(波长、强度等)的远距控制装置。将具有不同光学参数的滤光片(或孔径)置于转盘的不同位置,并对其编码。通过对编码值与预置值的比较,驱动步进马达带动转盘到所需的位置。仪器操作简便,有良好的重复性。     

窄等离子体吸收谱线宽度的纳米金锥用于光声成像

无损光声成像技术结合了纯光学成像高选择特性和纯超声成像中深穿透特性的优点,克服了光散射限制,实现了对活体深层组织的高分辨、高对比度成像。该成像技术对内源物质例如脱氧血红蛋白、含氧血红蛋白、黑色素、脂质等进行成像,提供了活体生物组织结构和功能信息,已经在生物医学领域表现出巨大的应用前景。然而,很多与病理过程相关的特征分子的光吸收能力较弱,在活体环境中难以被光声成像系统所识别,从而限制了光声成像技术的应用范围。基于功能纳米探针的光声成像-光声分子成像极大拓展光声成像的应用范围,可以在活体层面对病理过程进行分子水平的定性和定量研究,将为实现目标疾病的早期诊断提供强大的技术支持。本文发展在近红外具有窄吸收线宽(半高宽仅为60 nm)的纳米金锥作为新型的光声探针。通过选择不同径长比的纳米金锥,可以任意调节纳米金锥的吸收峰。通过调谐激光器的波长,可实现对不同吸收峰纳米金锥的选择性激发。纳米金锥将有可能用于多光谱光声成像,实现对不同靶标的目标分子探测。     

Analytical theory for the fluence,planar fluence,energy fluence,planar energy fluence and absorbed dose of primary particles and their fragments in broad therapeutic light ion beams

The purpose of the present work is to develop analytical expressions for the depth variation of the fluence, planar fluence, the energy fluence, planar energy fluence, the mean energy and absorbed dose of primary ions and their associated fragments in tissue-like media with ranges of clinical interest. The analytical expressions of the primary ions and associated fragments take into account nuclear interactions, energy losses, range straggling and multiple scattering. The analytical models of the radiation field quantities were compared with the results of the modified Monte Carlo (MC) code SHIELD-HIT₊. The results show that the shape of the depth absorbed dose distribution of the primary particles is characterized by an increasingly steep exponential fluence decrease with depth as the charge and atomic weight increase. This is accompanied by a compensating increased energy loss towards the Bragg peak as the charge of the ion increases. These largely compensating mechanisms are the main reason that the depth absorbed dose curve of all light ions is surprisingly similar. In addition, a rather uniform dose in the plateau region is obtained since the increasing fragment production almost precisely compensates the loss of primaries. The dominating light fragments such as protons and alpha particles are characterized by longer ranges than the primaries and their depth dose curves to some extent coincide well with the depth fluence curves due to a rather slow variation of mean stopping powers. In contrast, the heavier fragments are characterized by the build up of a slowing down spectrum similar to that of the primaries but with initially slightly shorter or longer ranges depending on their mass to atomic number ratio. The presented analytical theory for the light ion penetration in matter agree quite well with the MC and experimental data and may be very useful for fast analytical calculations of quantities like mean energy, fluence, energy fluence, absorbed dose, and LET.     

EFFECTS OF PHOTON FLUENCE RATE AND LIGHT SPECTRUM COMPOSITION ON GROWTH,PHOTOSYNTHESIS AND PIGMENT RELATIONS IN GRACILARIA SP.1

The optimal photon fluence rate for growth of tha llus tips of Gracilaria sp. was low (about 100 μE·^–2·¹); higher photon fluence rates inhibited growth. Both phycoerythrin (PE) and chlorophyll (chl) contents decreased with increasing photon fluence rates (up to 100 μE·–m^–2s^–1) in a fashion inverse to the growth response. Chl/PE ratios varied directly as the growth response over a larger photon fluence rate range. The peak chl/PE ratios were obtained at a photon fluence rate optimal for growth, suggesting that this parameter may be used to estimate in situ growth rates. A low compensation point (about 7 μE·^–2s^–1) was observed for low light (15 μE·^–2s^–1) grown plants. This compensation point was also obtained for growth in the long–term (5–6 weeks) experiments. Plants grown at 60 and 140 μE·^–2s^–1 showed higher light compensation and saturation points, suggesting that the variations in pigment composition found between the different treatments determine the photosynthetic responses at sub–optimal photon fluence rates. Photosynthetic rates at light saturation were the same, on a biomass basis, for plants grown at the various photon fluence rates. Thus, the photosynthetic dark reactions were not influenced by previous light regimes. It is suggested that maximal photosynthetic rates expressed on a biomass basis better reflect the potential productivity at tight saturation than if expressed on a pigment basis. Gracilaria sp. grew better under non–filtered fluorescent and greenish than under reddish and blue–enriched light of equal and sub–optimal photon, fluence rate. However, the pigment relations of the algae did not change in a direction complementary to the light composition at which they grew. This, together with the relatively higher photosynthetic rates under reddish and blueish light for plants previously grown under reddish and blueish light, suggests that adaptations to variouslight spectra are based on mechanisms different from complementary chromatic adaptation of the pigments.     

Heat generation in laser irradiated tissue

Many medical applications involving lasers rely upon the generation of heat within the tissue for the desired therapeutic effect. Determination of the absorbed light energy in tissue is difficult in many cases. Although UV wavelengths of the excimer laser and 10.6 microns wavelength of the CO2 laser are absorbed within the first 20 microns of soft tissue, visible and near infrared wavelengths are scattered as well as absorbed. Typically, multiple scattering is a significant factor in the distribution of light in tissue and the resulting heat source term. An improved model is presented for estimating heat generation due to the absorption of a collimated (axisymmetric) laser beam and scattered light at each point r and z in tissue. Heat generated within tissue is a function of the laser power, the shape and size of the incident beam and the optical properties of the tissue at the irradiation wavelength. Key to the calculation of heat source strength is accurate estimation of the light distribution. Methods for experimentally determining the optical parameters of tissue are discussed in the context of the improved model.     

光疗及光照剂量对抑郁症的作用研究进展

抑郁症是一种患病率高、易复发、自杀率高的精神障碍疾病，容易导致认知功能损伤等问题. 光疗以无创、副作用小、疗效快等优势受到广泛的关注，为调节抑郁症生物节律和睡眠障碍等症状提供了新的可能性. 光信号通过视网膜神经节细胞投射到抑郁脑区参与非视觉成像功能，激活神经细胞活动，分泌神经递质使神经通路产生生理性改变，对生物机体的昼夜节律、情绪、睡眠产生调控作用，达到改善抑郁行为的目的. 光的波长、剂量和最佳作用模式与治疗效果息息相关，但目前光疗的最佳应用模式仍存在争议. 为了全面促进光疗在生命科学领域以及临床上的应用，仍需进行大量的临床与模型动物光学参数研究. 本文从光疗路径、不同光谱作用机制、光学参数、作用疗效、存在问题及展望进行综述，促进光疗调控抑郁症的深入研究.     

The role of oxygen monitoring during photodynamic therapy and its potential for treatment dosimetry.

Understanding of the biology of photodynamic therapy (PDT) has expanded tremendously over the past few years. However, in the clinical situation, it is still a challenge to match the extent of PDT effects to the extent of the disease process being treated. PDT requires drug, light and oxygen, any of which can be the limiting factor in determining efficacy at each point in a target organ. This article reviews techniques available for monitoring tissue oxygenation during PDT. Point measurements can be made using oxygen electrodes or luminescence-based optodes for direct measurements of tissue pO2, or using optical spectroscopy for measuring the oxygen saturation of haemoglobin. Imaging is considerably more complex, but may become feasible with techniques like BOLD MRI. Pre-clinical studies have shown dramatic changes in oxygenation during PDT, which vary with the photosensitizer used and the light delivery regimen. Better oxygenation throughout treatment is achieved if the light fluence rate is kept low as this reduces the rate of oxygen consumption. The relationship between tissue oxygenation and PDT effect is complex and remarkably few studies have directly correlated oxygenation changes during PDT with the final biological effect, although those that have confirm the value of maintaining good oxygenation. Real time monitoring to ensure adequate oxygenation at strategic points in target tissues during PDT is likely to be important, particularly in the image guided treatment of tumours of solid organs.     

Effect of light quality (blue, red) and fluence rate on the synthesis of pigments and pigment-proteins in maize and black pine mesophyll chloroplasts

Maize ( Zea mays L. hybrid ZP-704) and black pine ( Pinus nigra Arn.) were grown for five days at low fluence rate (0.4–4.0, μmol m^–2 s⁻¹) in blue or red light. Compared to red light of the same fluence rate, blue light effects in maize were repressive for the accumulation of Chita, b , carotenoids and light-harvesting complex-2 (LHC-2) proteins. The maximal reduction of proteins bound to the light-harvesting complex of photosystem 2 and pigments was attained at different fluence rate levels. In black pine, blue light compared to the red of the same fluence rate level either activated or reduced accumulation of pigments and LHC proteins, the effect being dependent on its fluence rate level. At fluence less than 3.0 μmol m⁻² s⁻¹ blue light was more efficient for the synthesis of Chi a, b and carotenoids, hut for LHC-2 complexes, fluence rates between 0.4 and 1.5 [μmol m⁻² s⁻¹ were more effective. In pine the effects of the two lights on the accumulation of pigments and LHC proteins were demonstrated separately and were dependent on fluence rate level. This suggests irradianoe-controlled activation/deactivation of the photoreceptor at the level of the cell.     

Hypocotyl growth in Sinapis alba L: the roles of light quality and quantity

Abstract. A comparison is made of the relative effectiveness of light quality and light quantity on the elongation growth of Sinapis alba hypocotyls. The results show that hypocotyl extension rate in plants which have not previously been exposed to light is controlled primarily by the prevailing photon fluence rate when the phytochrome photostationary state lies between ∼0.033 and ∼0.81. Below ∼0.033, changes in photostationary state also have a marked effect on extension rate. Elongation growth in light-adapted plants is controlled by both photon fluence rate and the spectral quality of the incident radiation at all photoequilibria. Photosynthesis can modify these responses but is not essential as a prior condition for a green plant to respond to changes in light quality and quantity.