红细胞低温显微动态图象处理技术的建立和应用研究

本文报道了一种新型的低温生物学实验系统——红细胞低温显微动态图象处理系统,该系统将先进的计算机控温、图象处理技术和低温显微镜及摄录象机有机地联成一体。将此技术应用于红细胞的低温冰冻保存实验,具有能实时记录血细胞在冰冻过程中的实验参数(如时间、温度、降温速率等)与细胞图象,能对其图象处理及面积、体积测量,也能使细胞呈现伪彩色及测定红细胞冰冻损伤程度。该系统是一新的综合性的低温生物学研究仪器,对研究器官保存与移植具有明显意义。     

活体细胞运动变形参数的计算机图象分析的研究

在生物学研究中,通常提供的图象信息是静止的,但在实际工作中分析活体样品是十分重要的,运动图象的分析更接近于生物体的客观情况,为此,我们建立了运动图象的计算机图象分析方法和应用软件。该研究主要解决运动信息的抽取、检出和运动向量的测算,方法有下     

昆虫数学形态学研究及其应用展望

数学形态学是用数学方法描述或分析一个物体图象的形状的理论和方法,是图象处理和图象识别技术的发展,但在生物学当中的应用还很有限。本文介绍了一个新的分支学科——昆虫数学形态学,包括三方面的内容：①昆虫数学形态学技术研究,涉及昆虫图象数字化技术和昆虫图象处理与识别技术;②昆虫数学形态学理论研究,主要以昆虫图象的解释和理解研究及昆虫数学形态学与分类学等学科的关系研究为主;③昆虫和昆虫数学形态学应用基础研究,涉及昆虫数学形态学数据库及其分析软件开发,昆虫图象的机器学习和计算机视觉等内容。昆虫数学形态学理论和方法与计算机视觉技术相结合,在害虫虫情监测、昆虫多媒体专家系统的构建等方面具有广阔的应用前景。     

基于视觉编码的图象处理研究──Ⅰ．原理、算法及实现

提出Ｇａｂｏｒ小波表达的概念及其在图象处理中实现的数学模型和算法框架,主要解决了运算中非正交性问题、收敛性问题,使得该算法及模型可以实现图象的分解和重建,并且可以应用于对视觉编码理论的解释。     

细胞图象分析仪的研制及其对细胞DNA含量测定的初探

本文介绍在微机上开发的细胞图象处理分析系统,该系统图象处理功能强,细胞测量参数多,操作简便,实用性强。可用于生物医学图象的处理和分析。     

乳腺X线片的计算机图象处理

本文叙述了用S-500图象机处理乳腺X线片的方法、结果及其对乳腺良恶性病变鉴别诊断的临床价值,着重介绍了分段线性灰度变换、空间变量对比度增强、直方图强度线性扩展和伪彩色等处理手段在改善原片清晰度、揭示病灶特征方面的应用,文章还讨论了影响图象处理质量的诸多因素,提出了图象处理过程中尚待解决的一些技术问题。     

基于视觉编码的图象处理研究──Ⅰ．原理、算法及实现

提出Ｇａｂｏｒ小波表达的概念及其在图象处理中实现的数学模型和算法框架,主要解决了运算中非正交性问题、收敛性问题,使得该算法及模型可以实现图象的分析和重建,并且可以应用于对视觉编码理论的解释。     

红细胞在微血管狭窄处的力学行为

红细胞的流变能力在整个人体微循环系统中至关重要. 本文采用有限元法结合动网格技术, 对红细胞穿越微血管狭窄处的过程进行了计算机数值模拟. 研究对象包括血浆、红细胞膜、细胞质及微血管狭窄处. 模拟涉及了血浆、细胞质与红细胞膜之间的流固耦合作用以及红细胞膜与微血管狭窄处的接触问题. 结果表明, 红细胞穿越微血管狭窄处的能力受血浆流速与红细胞表面积-体积比的影响较为显著, 且在保持血浆流速不变的条件下, 升高的血浆黏度在一定范围内有助于红细胞穿越微血管狭窄处. 由此认为, 病理状态下微循环内血液流变能力的降低在很大程度上归因于白细胞的增多, 进而引发红细胞的聚集及血液结构的改变. 本研究作为血液流变学的基础研究, 目的在于为临床血液流变学提供一定的理论基础.     

模拟糖尿病大鼠红细胞粘附的研究

目的：观察糖尿病时红细胞的粘附,探讨红细胞粘附对糖尿病微血管病变的影响。方法：ＳＴＺ诱发大鼠糖尿病,ＦＩＴＣ体外标记糖尿病红细胞后输给正常大鼠,荧光显微镜观察怕糖尿病红细胞在正常大鼠软脑膜微血管中的流动;透射电镜观察糖尿病大鼠脑皮质微血管内红细胞的超微结构。结构：与正常红细胞相比,ＦＩＴＣ标记的糖尿病红细胞在血液正常的大鼠脑微血管中可以较长时间停留在内皮细胞表面,不被血流冲走,提示红细胞对微血管内     

对地贫红细胞的显微激光散射和图象分析

应用显微准弹性激光散射(MQLS)技术与显微生物医学图象分析技术对地中海贫血红细胞及胞内血红蛋白动态特性进行了研究.在实验中,比较了正常人及地贫患者红细胞胞内血红蛋白聚集体的平均流体力学半径、平均平动扩散系数及红细胞膜的搏动频率等动态特性参数,以及细胞的截面积、规化形状因子、长径、短径、灰度等图象分析数据,发现地贫红细胞的血红蛋白聚合物平均流体力学半径远远大于正常人红细胞的,其大小变异亦较正常人大,且其膜搏动频率也较为缓慢,细胞的截面积也变小.这反映了地贫红细胞内有较大的蛋白质聚合物存在和红细胞变形能力差的特性.研究还表明,显微准弹性激光散射技术结合图象分析技术,可使测量的可比性和准确性大大提高,预期可广泛适用于各种活细胞动态特性的研究.     

视觉运动图象滤波模型及其实时模拟

在充满生存竞争的动物世界,视觉的伪装与反伪装现象随处可见,视觉反伪装的原理是什么？本文对Ｒｅｉｃｈａｒｄｔ的图形－背景相对运动分辨模型加以发展,提出了视觉反伪装功能的运动图象滤波器模型。为了检验此模型,我们建立了一个生物学似真的实时运动信息加工神经网络电子装置,实现了实时、高分辨运动目标图象滤波。与Ｍｅａｄ的人工视网膜的运动目标图象检测功能相比,检测的运动目标图象的分辨率有很大提高,而噪声水平显著降低,克服了人工视网膜的一些局限性。     

REGULATION OF HAEMOPOIESIS IN ALTERED GRAVITY

(1) The aetiology of one of the most striking physiological changes occurring during space-flight, the loss of red blood cells, remains unknown, and its precise time-pattern in flight has not yet been studied. (2) It is suggested that the changes during space-flight responsible for loss of red blood cells in man are (a) loss of plasma volume resulting from disappearance of hydrostatic pressure in the circulation during weightlessness and (b) reduced energy expended in maintenance of form, posture and locomotion resulting from elimination of the usual gravitational load on the muscles. Quadrupeds, like rats, would be expected to suffer minimal blood shifts in weightlessness and therefore have an unchanged plasma volume. However, since in weightlessness the activity-related energy expenditure by the muscles is reduced, the accompanying reduced oxygen demand by the tissues would cause a reduction in erythropoietin levels and so in the production of red blood cells, and a progressive lowering of the total red blood cell mass toward a new steady-state level. (3) Loss of plasma volume alone does not explain the observed loss of red blood cells in astronauts because, in the three manned Skylab missions, as the duration of the missions increased, loss of red blood cell mass decreased, whereas loss of plasma volume increased. This discrepancy is, however, well accounted for by the above hypothesis by taking into consideration the increased level of exercise of the astronauts as the duration of the mission increased. (4) Though water submersion of human subjects does mimic the effects of weightlessness, such effects were overriden in sea mammals because of adaptation to other factors associated with a life in the sea. (5) From the presented analysis of haemopoietic changes observed in spaceflight, an experiment can be designed for a future flight to uncover the causes and mechanisms of these changes and provide a basis for developing protective measures. Thus, the space environment can be used as an investigative tool to enhance the knowledge of the function of the haemopoietic system, which is a major homeostatic system of man and other vertebrates.     

四种鱼类外周血红细胞细胞周期及DNA含量

通过流式细胞仪测量了兴国红鲤（Ｃｙｐｒｉｎｕｓ ｃａｒｐｉｏ Ｖａｒ． Ｓｉｎｇｕｏｎｅｎｓｉｓ）、奥利亚罗非鱼（Ｓａｒｏｔｈｅｒｏｄｏｎ ａｕｒｅａ）、 鳙（Ａｒｉｓｔｉｃｈｔｈｙｓ ｎｏｂｉｌｉｓ Ｒ．）和团头鲂（Ｍｅｇａｌｏｂｒａｍａ ａｍｂｌｙｃｅｐｈａｌａ Ｙｉｎ．）红细胞的ＤＮＡ含量,四种鱼与鸡红细胞ＤＮＡ含量的比值分别为１·６５、０．９６、０．９１、１·１５,以鸡红细胞ＤＮＡ含量２．３ｐｇ／Ｎ计算,四种鱼二倍体体细胞的 ＤＮＡ含量分别为３．８０ ｐｇ／Ｎ, ２． ２２ｐｇ／Ｎ、２． ０８ｐｇ／Ｎ、 ２． ６６ｐｇ／Ｎ。另外,四种鱼外周血红细胞分别有２６％、 ２６％、 ２３％、 ２４％的细胞处于 ＤＮＡ合成期（Ｓ）,ＤＮＡ合成后期（Ｇ２）和分裂期（Ｍ）,这表明这四种鱼类的外周血红细胞并非失去分裂能力的特化细胞群,它们表现了较强的细胞周期现象。这有可能是这几种硬骨鱼类外周血仍具有造血功能的缘故。     

Biological computation of image motion from flows over boundaries.

A theory of early motion processing in the human and primate visual system is presented which is based on the idea that spatio-temporal retinal image data is represented in primary visual cortex by a truncated 3D Taylor expansion that we refer to as a jet vector. This representation allows all the concepts of differential geometry to be applied to the analysis of visual information processing. We show in particular how the generalised Stokes theorem can be used to move from the calculation of derivatives of image brightness at a point to the calculation of image brightness differences on the boundary of a volume in space-time and how this can be generalised to apply to integrals of products of derivatives. We also provide novel interpretations of the roles of direction selective, bi-directional and pan-directional cells and of type I and type II cells in V5/MT.     

Blood flow in the capillary bed

From arteries to veins, the blood has to go through the ‘capillary’ blood vessels. These blood vessels are so small that often their diameter is smaller than that of the red blood cells. Intimate interactions occur, therefore, between the blood cells and the blood vessels.

A general survey of recent works on capillary blood flow is given in this article. Some details are presented for two problems: the problem of deformation of the flexible red blood cells, their motion in the capillary blood vessels, and the pressure drop due to the red cell blood vessel interaction; and the problem of the flow of plasma ‘bolus’ between neighboring red cells.

The solution supplies many details about the microcirculation phenomenon. Taken together, a method is offered for the calculation of pressure drop in the capillary as a function of various physical parameters: the red cell volume per unit blood volume, (hematocrit), the ratio of the cell diameter to the blood vessel diameter, the ratio of the length of the blood vessel to its length, the volume of individual red cells, and a parameter relating the cell membrane elasticity, plasma viscosity and the cell velocity.     

THE AGGLUTINATION OF RED BLOOD CELLS IN THE PRESENCE OF BLOOD SERA

1. The addition of blood serum displaces the optimum for agglutination of red blood cells in a salt-free medium to the reaction characteristic of flocculation of the serum euglobulin. 2. This effect is not due merely to a mechanical entanglement of the cells by the precipitating euglobulin, since at reactions at which the latter is soluble it protects the cells from the agglutination which occurs in its absence. 3. A combination of some sort appears therefore to take place between sheep cells and sheep, rabbit, and guinea pig serum euglobulin, and involves a condensation of the serum protein upon the surface of the red cell. 4. At the optimal point for agglutination of persensitized cells both mid- and end-piece of complement combine with the cells. 5. Agglutination is closely related to an optimal H ion concentration in the suspending fluid, and probably of the cell membrane, and not to a definite reaction in the interior of the cell.     

Movement correction of digital sequence angiographies of the retina]

Retinal hemodynamics can be quantified from videoangiographic image sequences by digital image processing. Intensity changes of dye dilution curves provide dynamics parameters of the local retinal blood flow. The measuring points of dye dilution curves have to be fixed on identical image contents in each image of a complete image sequence. To obtain measurements for every pixel on the retinal surface a motion-compensated image sequence is required. A new method adapted to the compensation of eye motion and movement artifacts in Scanning Laser Ophthalmoscopy in long image sequences (300-500 images) is presented in this paper. To inhibit error propagation of time sequential motion estimation, the eye movement is divided into two dynamic movements components. The method presented permits compensation for eye motion in retinal fluorescein angiographic sequences. Owing to the short calculation times, this algorithm can be used in clinical routine.     

蝇髓部细胞的运动敏感性

用细胞外记录方法研究了蝇髓部细胞的运动敏感性.实验证明,在蝇髓部有运动敏感型细胞,它们的主要特点是对运动敏感,但不具有方向选择性.其主要性质如下:1.有些细胞对闪光刺激给出超极化反应,有些则为去极化反应;2.对运动反应,但不具有方向性;3.有些对大视场的运动敏感,有些则对小视场的运动敏感;4.反应幅度与图形运动速度有关;5.感受野为简单型,并且不很大.对于可能对应的算法进行了讨论.     

VISUAL ACUITY AND ILLUMINATION IN DIFFERENT SPECTRAL REGIONS

The relation between visual acuity and illumination was measured in red and blue light, using a broken circle or C and a grating as test objects. The red light data fall on single continuous curves representing pure cone vision. The blue light data fall on two distinct curves with a transition at about 0.03 photons. Values below this intensity represent pure rod vision. Those immediately above represent the cooperative activity of rods and cones, and yield higher visual acuities than either. Pure cone vision in this intensity region is given by central fixation (C test object). All the rest of the values above this transition region represent pure cone vision. In blue light the rod data with the C lie about 1.5 log units lower on the intensity axis (cone scale) than they do in white light, while with the grating they lie about 1.0 log unit lower than in white light. Both the pure rod and cone data with the C test object are precisely described by one form of the stationary state equation. With the grating test object and a non-limiting pupil, the pure rod and cone data are described by another form of the same equation in which the curve is half as steep. The introduction of a small pupil, which limits maximum visual acuity, makes the relation between visual acuity and illumination appear steeper. Determinations of maximum visual acuities under a variety of conditions show that for the grating the pupil has to be larger, the longer the wavelength of the light, in order for the pupil not to be the limiting factor. Similar measurements with the C show that when intensity discrimination at the retina is experimentally made the limiting factor in resolution, visual acuity is improved by conditions designed to increase image contrast. However, intensity discrimination cannot be the limiting factor for the ordinary test object resolution because the conditions designed to improve image contrast do not improve maximum visual acuity, while those which reduce image contrast do not produce proportional reductions of visual acuity.