南京地区太阳辐射资源量子年总量的理论计算

为了从量子角度探讨南京地区的太阳辐射资源,在理想大气条件下对2008年南京地区的光合有效辐射波段的量子辐射进行了计算.在2008年的366天中每隔20分钟计算一次量子照度,然后通过累积计算得到太阳直接辐射年总量.应用相关公式,计算出了散射辐射年总量,总辐射年总量和光合有效辐射年总量.经过与一些相关资料的对比分析,认为计算结果正确合理.     

视网膜单细胞成像技术研究

建立了一台基于37单元变形镜、Shack-hartman波前像差传感器和12位科研级CCD相机的自适应光学视网膜相机。采用一个中心波长为679nm的超辐射二极管(SLD)作为相机的光源,通过将超辐射二极管和多模光纤耦合,显著减小了SLD光源的空间相干性,从而消除了散斑噪声对成像的影响。多模光纤的输出提供了一种高亮度、均匀照明的光源,使人眼视网膜单细胞成像的速度达到4．8幅／秒。     

铬酸钾溶液紫外吸收特征及在研究UV-B生物学效应中的应用

为了更好地利用铬酸钾溶液去除UV-B光源中的UV-A和UV-C,对不同浓度和pH值的铬酸钾溶液的紫外吸收特征及其稳定性进行了相关研究.并在相同剂量UV-B作用下,对地木耳(Nostoc commune UETX-584)光合生理活性和生化组分在UV-B光源直接照射和经过铬酸钾过滤后照射的变化进行了对比研究.结果表明,铬酸钾溶液在pH值为8、0.4 mmol/L时可以有效滤除UV-B光源中的UV-C和大于340 nm的UV-A.相对于经过铬酸钾溶液过滤的UV-B光源,未过滤的UV-B光源显著抑制了地木耳的生长、叶绿素合成、Fv/Fm、最大光合作用速率和集光效率,显著促进了MAAs(三苯基咪唑类氨基酸)等吸收紫外辐射色素的合成.相对于无紫外辐射的地木耳来说,经过铬酸钾溶液过滤的UV-B对地木耳的生长影响不明显,但是其促进了紫外吸收色素的合成,抑制了Fv/Fm、最大光合作用速率和集光效率.     

UVA的辐射效应及其分子机理

在光量子血疗法治疗肿瘤及其它疾病中,紫外线已被广泛地用作辐照光源,并取得满意效果。本文综述了近几年关于ＵＶＡ的辐射效应和分子机制研究的某些进展。     

维生素B12的光解研究及发酵液中维生素B12检测新方法的建立

采用HPLC检测法研究5,脱氧腺苷钴胺素和甲基基钴胺素的水溶液在不同光源及不同照度下的光解情况,结果表明随着光能量的增加光解速度加快。利用脱氧腺苷钴胺素的光解性质,探索了一种检测发酵液中维生素B12含量的新方法。将含有钴胺素的细胞破碎液完全光解后,测定光解后的产物羟基钴胺素,以此来确定维生素B12产量。此方法简便快速、重复性好,可应用于发酵生产维生素B12的各个环节。     

紫外光源及太阳UV-B辐射的模拟实验

介绍了用于UV-B生物学效应研究的几种常见光源,对如何利用选择性薄膜获得理想的UV-B波段的光谱,进而能较真实模拟平流层O3耗损所导致的近地表面太阳UV-B辐射的增强,以及在野外进行UV-B模拟研究时,紫外荧光灯管的排列方式等进行了分析讨论。介绍并讨论了当前UV-B辐射实验的各种方法,并就各实验设计的注意事项和安全操作等提出了建议。     

稀有鮈鲫对不同生境的选择性偏好

对不同生境的识别和选择性偏好是保障鱼类生存和繁衍的重要能力之一。以稀有鮈鲫（Gobiocypris rarus）为研究对象,使用沙、水草和石块在观测水缸中进行多种排列组合以构建不同的生境类型,基于在各区域的停留时长和中线跨越次数两项参数,测试稀有鮈鲫对不同生境类型的偏好以及营养状态、生境组成物数量、环境照度对该行为影响。结果表明,稀有鮈鲫对不同的生境类型具有明显的选择性偏好,对仅水草生境偏好程度最高,对仅石块生境的偏好程度最低。该偏好行为在24 h的禁食后变化不显著（P > 0.05）,但生境组成物数量和环境照度对该行为具有显著影响（P < 0.05）,其偏好程度随水草数量和照度的增加而增加,在包含8棵水草及1 000 lx的照度下最高。     

低照度光疗法在脑损伤疾病治疗方面的研究进展

由于传统方法在脑疾病治疗方面的局限性,低照度光疗法越来越受到重视。低照度光疗法利用波长在600 nm-1 100 nm的低功率激光或者准单色光以非破坏和非热行为来调制生物过程,用于促进伤口愈合,抑制感染、水肿以及减轻疼痛等。近来,研究者进行了大量低照度光治疗脑损伤疾病方面的实验,研究对象从细胞、动物模型到人类,病症从卒中,急性脑创伤到慢性脑损伤以及神经退行性病变等。研究结果表明,低照度光疗法有可能应用于脑部损伤疾病的治疗。介绍了低照度光疗法的机理、应用,并对低照度光疗法的治疗参数,包括治疗窗口、波长以及剂量等进行了回顾。     

田间增加紫外线（UV）辐射对大豆幼苗生长和光合作用的影响

 两个增加的UV(UV-AB,280～400nm)辐射强度分别相当于大气臭氧减少3.6％和5.1％时增加的UV-B辐射。UV辐射增强明显降低大豆的株高、叶面积、干重、水分含量和叶绿素含量,大豆生长受抑程度随人工UV光源照射时间和强度增加而增强,是增加UV辐射剂量的累积效应,叶绿素b的降幅大于叶绿素a,表明UV辐射对大豆幼苗捕光色素的破坏较严重。同时,增加UV辐射还使大豆幼苗的表观光合速率、蒸腾速率、水分利用效率、气孔导度下降,作用效果与辐射强度正相关。与生长等比较,UV辐射条件下,冠／根比值减少幅度不大。分析认为,大豆幼苗生长和光合能力的下降可以使植物避免或减轻UV辐射的进一步伤害,对植物适应UV辐射有利。     

光照对大泷六线鱼仔鱼摄食量的影响

对不同照度下大泷六线鱼仔鱼摄食量进行了初步测定,得知仔鱼在１００Ｌｘ时摄食量最大,其次为１０Ｌｘ,摄食率为１００Ｌｘ时最高,并在２０分钟时达到最大值,可见大泷六线仔鱼的适宜照度范围为１０－１００Ｌｘ,高或低于此照度都会影响仔鱼的摄食效果。     

Photoreceptor spectral sensitivity of the compound eyes of black soldier fly (Hermetia illucens) informing the design of LED-based illumination to enhance indoor reproduction

Mating in the black soldier fly (BSF) is a visually mediated behaviour that under natural conditions occurs in full sunlight. Artificial light conditions promoting mating by BSF were designed based on the spectral characteristics of the compound eye retina. Electrophysiological measurements revealed that BSF ommatidia contained UV-, blue- and green-sensitive photoreceptor cells, allowing trichromatic vision. An illumination system for indoor breeding based on UV, blue and green LEDs was designed and its efficiency was compared with illumination by fluorescent tubes which have been successfully used to sustain a BSF colony for five years. Illumination by LEDs and the fluorescent tubes yielded equal numbers of egg clutches, however, the LED illumination resulted in significantly more larvae. The possibilities to optimize the current LED illumination system to better approximate the skylight illuminant and potentially optimize the larval yield are discussed.     

Light-emitting diodes in modern microscopy--from David to Goliath?

Proper illumination is essential for light microscopy. Whereas in early years incandescent light was the only illumination, today, more and more specialized light sources, such as lasers or arc lamps are used. Because of the high efficiency and brightness that light-emitting diodes (LED) have reached today, they have become a serious alternative for almost all kinds of illumination in light microscopy. LED have a high durability, do not need expensive electronics, and they can be switched in nanoseconds. Besides this, they are available throughout the UV/Vis/NIR-spectrum with a narrow bandwidth. This makes them ideal light sources for fluorescence microscopy. The white LED, with a color temperature ranging from 2,600 up to 5,000 K is an excellent choice for bright-field illumination with the additional advantage of simple brightness adjustments without changing the spectrum. This review discusses the different LED types, their use in the fluorescence microscope, and discusses LED as specialized illumination sources for F?rster resonance energy transfer and fluorescent lifetime imaging microscopy.     

Artifact‐free objective‐type multicolor total internal reflection fluorescence microscopy with light‐emitting diode light sources—Part I

Total internal reflection fluorescence excitation (TIRF) microscopy allows the selective observation of fluorescent molecules in immediate proximity to an interface between different refractive indices. Objective‐type or prism‐less TIRF excitation is typically achieved with laser light sources. We here propose a simple, yet optically advantageous light‐emitting diode (LED)‐based implementation of objective‐type TIRF (LED‐TIRF). The proposed LED‐TIRF condenser is affordable and easy to set up at any epifluorescence microscope to perform multicolor TIRF and/or combined TIRF‐epifluorescence imaging with even illumination of the entire field of view. Electrical control of LED light sources replaces mechanical shutters or optical modulators. LED‐TIRF microscopy eliminates safety burdens that are associated with laser sources, offers favorable instrument lifetime and stability without active cooling. The non‐coherent light source and the type of projection eliminate interference fringing and local scattering artifacts that are associated with conventional laser‐TIRF. Unlike azimuthal spinning laser‐TIRF, LED‐TIRF does not require synchronization between beam rotation and the camera and can be monitored with either global or rolling shutter cameras. Typical implementations, such as live cell multicolor imaging in TIRF and epifluorescence of imaging of short‐lived, localized translocation events of a Ca²⁺‐sensitive protein kinase C α fusion protein are demonstrated.     

Effects of nocturnal illumination on life-history decisions and fitness in two wild songbird species

The effects of artificial night lighting on animal behaviour and fitness are largely unknown. Most studies report short-term consequences in locations that are also exposed to other anthropogenic disturbance. We know little about how the effects of nocturnal illumination vary with different light colour compositions. This is increasingly relevant as the use of LED lights becomes more common, and LED light colour composition can be easily adjusted. We experimentally illuminated previously dark natural habitat with white, green and red light, and measured the effects on life-history decisions and fitness in two free-living songbird species, the great tit (Parus major) and pied flycatcher (Ficedula hypoleuca) in two consecutive years. In 2013, but not in 2014, we found an effect of light treatment on lay date, and of the interaction of treatment and distance to the nearest lamp post on chick mass in great tits but not in pied flycatchers. We did not find an effect in either species of light treatment on breeding densities, clutch size, probability of brood failure, number of fledglings and adult survival. The finding that light colour may have differential effects opens up the possibility to mitigate negative ecological effects of nocturnal illumination by using different light spectra.     

Effect of blue light‐emitting diode light and antioxidant potential in a somatic cell

Light is an indispensable part of routine laboratory work in which conventional light is generally used. Light‐emitting diodes (LEDs) have come to replace conventional light, and thus could be a potent target in biomedical studies. Since blue light is a major component of visible light wavelength, in this study, using a somatic cell from the African green monkey kidney, we assessed the possible consequences of the blue spectra of LED light in future animal experiments and proposed a potent mitigation against light‐induced damage. COS‐7 cells were exposed to blue LED light (450 nm) and the growth and deoxyribonucleic acid (DNA) damage were assessed at different exposure times. A higher suppression in cell growth and viability was observed under a longer period of blue LED light exposure. The number of apoptotic cells increased as the light exposure time was prolonged. Reactive oxygen species (ROS) generation was also elevated in accordance to the extension of light exposure time. A comparison with dark‐maintained cells revealed that the upregulation of ROS by blue LED light plays a significant role in causing cellular dysfunction in DNA in a time‐dependent manner. In turn, antioxidant treatment has been shown to improve cell growth and viability under blue LED light conditions. This indicates that antioxidants have potential against blue LED light‐induced somatic cell damage. It is expected that this study will contribute to the understanding of the basic mechanism of somatic cell death under visible light and maximize the beneficial use of LED light in future animal experiments.     

Enhancing the growth of Physcomitrella patens by combination of monochromatic red and blue light - a kinetic study

In the current work we demonstrate the relevance of monochromatic light conditions in moss plant cell culture. Light intensity and illumination wavelength are important cultivation parameters due to their impact on growth and chlorophyll formation kinetics of the moss Physcomitrella patens. This moss was chosen as a model organism due to its capability to produce complex recombinant pharmaceutical proteins. Filamentous moss cells were cultivated in mineral medium in shaking flasks. The flasks were illuminated by light emitting diodes (LED) providing nearly monochromatic red and blue light as well as white light as a reference. A maximum growth rate of 0.78 day((1) was achieved under additional CO(2) aeration and no growth inhibition was observed under high light illumination. The application of dual red and blue light is the most effective way to reach high growth and chlorophyll formation rates while minimizing energy consumption of the LEDs. These observations are discussed as effects of photo sensory pigments in the moss. The combination of monochromatic red and blue light should be considered when a large scale process is set up.     

Red Sea corals under Artificial Light Pollution at Night (ALAN) undergo oxidative stress and photosynthetic impairment

Coral reefs represent the most diverse marine ecosystem on the planet, yet they are undergoing an unprecedented decline due to a combination of increasing global and local stressors. Despite the wealth of research investigating these stressors, Artificial Light Pollution at Night (ALAN) or “ecological light pollution” represents an emerging threat that has received little attention in the context of coral reefs, despite the potential of disrupting the chronobiology, physiology, behavior, and other biological processes of coral reef organisms. Scleractinian corals, the framework builders of coral reefs, depend on lunar illumination cues to synchronize their biological rhythms such as behavior, reproduction and physiology. While, light pollution (POL) may mask and lead de‐synchronization of these biological rhythms process. To reveal if ALAN impacts coral physiology, we have studied two coral species, Acropora eurystoma and Pocillopora damicornis, from the Gulf of Eilat/Aqaba, Red Sea, which is undergoing urban development that has led to severe POL at night. Our two experimental design data revealed that corals exposed to ALAN face an oxidative stress condition, show lower photosynthesis performances measured by electron transport rate (ETR), as well as changes in chlorophyll and algae density parameters. Testing different lights such as Blue LED and White LED spectrum showed more extreme impact in comparison to Yellow LEDs on coral physiology. The finding of this work sheds light on the emerging threat of POL and the impacts on the biology and ecology of Scleractinian corals, and will help to formulate specific management implementations to mitigate its potentially harmful impacts.     

Advanced photobioreactor LED illumination system: Scale‐down approach to study microalgal growth kinetics

A newly designed and constructed LED illumination device for commercial cylindrical bioreactors is presented for application in microalgal cultivations and investigation of growth kinetics. An ideally illuminated volume is achieved by focusing the light toward the center of the reactor and thereby compensating the mutual shading of the cells. The relevant biomass concentration for homogeneous illumination depending on reactor radius was determined by light distribution measurements for Chlamydomonas to 0.2 g/L (equal 0.435 optical density at 750 nm). It is shown that cultivation experiments with the newly designed illumination device operated in batch mode can be successfully applied for determination of growth rates and photo conversion efficiencies. The exact knowledge of physiological reactions of specific strain(s) and the estimation of relevant parameters for scale‐up can be used for construction of economic pilot plant photobioreactors. The determination of light‐dependent kinetics of growth and product formation is the first necessary step to achieve this. A wide variety of different parameters can be examined like the effect of different illumination conditions (light intensity, frequency of day/night cycles, flashing light, light color…) and thereby for each single application specific, relevant, and interesting parameters will be examined.     

Effects of blue pulsed light on human physiological functions and subjective evaluation

Background

It has been assumed that light with a higher irradiance of pulsed blue light has a much greater influence than that of light with a lower irradiance of steady blue light, although they have the same multiplication value of irradiance and duration. We examined the non-visual physiological effects of blue pulsed light, and determined whether it is sensed visually as being blue.

Findings

Seven young male volunteers participated in the study. We placed a circular screen (diameter 500 mm) in front of the participants and irradiated it using blue and/or white light-emitting diodes (LEDs), and we used halogen lamps as a standard illuminant. We applied three steady light conditions of white LED (F0), blue LED + white LED (F10), and blue LED (F100), and a blue pulsed light condition of a 100-μs pulse width with a 10% duty ratio (P10). The irradiance of all four conditions at the participant''s eye level was almost the same, at around 12 μW/cm². We measured their pupil diameter, recorded electroencephalogram readings and Kwansei Gakuin Sleepiness Scale score, and collected subjective evaluations. The subjective bluish score under the F100 condition was significantly higher than those under other conditions. Even under the P10 condition with a 10% duty ratio of blue pulsed light and the F10 condition, the participant did not perceive the light as bluish. Pupillary light response under the P10 pulsed light condition was significantly greater than under the F10 condition, even though the two conditions had equal blue light components.

Conclusions

The pupil constricted under the blue pulsed light condition, indicating a non-visual effect of the lighting, even though the participants did not perceive the light as bluish.     

Uncertainty in Health Risks from Artificial Lighting due to Disruption of Circadian Rhythm and Melatonin Secretion: A Review

Incandescent lighting in many domestic and commercial applications is in the process of replacement by more efficient light sources, such as the compact fluorescent light (CFL) and the light emitting diode (LED). For household use, both CFL and LED sources have a significant blue component in the emitted spectrum in comparison to the warmer incandescent globes and this has been the cause of emerging health concerns. Recent research suggests that the blue light bandwidth in the visible spectrum has a significant impact on physical health, including disruption of the internal body clock and suppression of melatonin secretion at night. This disruptive effect has been linked to a range of illnesses, including breast cancer, prostate cancer, heart disease, obesity, and diabetes. There have also been positive effects observed, including re-setting the body clock to the required sleep pattern, boosting mood, alertness, cognitive performance, and alleviating seasonal affective depression (SAD). In this article, an introduction and review of recent research is provided, relevant health issues are highlighted and discussed, and uncertainty analysis completed for the dose–response curve for melatonin suppression as a function of incident photon density.