动物种质细胞的超低温冷冻保存

目前不少种类的动物种质细胞都可在超低温条件下保存,随着低温生物学和生殖生物学的不断发展,超低温保存技术也在不断发展,可以保存的动物种质细胞范围也在不断扩大。但目前超低温保存技术面临的困难和需要解决的问题是如何提高种质细胞冷冻保存的效果,寻求最佳冷冻方案,降低种质细胞的冷冻损伤,进而运用超低温冷冻技术保护物种的多样性。从目前的研究情况来看,动物种质细胞超低温保存的常用方法有程序降温法和玻璃化法。防冻     

去甲基万古霉素菌种低温冷冻、冷干保藏条件优化及10 年菌种保藏效果

【目的】针对去甲基万古霉素产生菌不耐保藏的问题,改进菌种保藏方法,对超低温液氮保藏、-80°C低温冷冻保藏、冷干保藏方法跟踪考察10年保藏稳定性,评价不同保藏方法对去甲基万古霉素产生菌的保藏适用性。【方法】采用甘油作基础保护剂进行超低温液氮保藏和-80°C低温冷冻保藏,采用脱脂牛奶作基础保护剂进行冷干保藏,针对超低温液氮保藏进行降温速率考察,研究非渗透性冷冻保护剂海藻糖、聚乙烯吡咯烷酮(PVP)等对3种保藏方法的冻存影响,对优选出的保藏方法进行10年跟踪考察。【结果】3种保藏方法冻后菌种存活率依次为:-80°C低温冷冻保藏超低温液氮保藏冷干保藏。液氮保藏最适降温速率为快速冷冻。优选出最佳保护剂配方:超低温液氮保藏为甘油8.0%,海藻糖3.5%;-80°C低温冷冻保藏为甘油6.0%,PVP 5.0%;冷干保藏为脱脂牛奶,6.0%海藻糖。采用优化保藏条件,液氮保藏10年存活率稳定在70.6%,菌种发酵水平为入藏水平的92.9%。【结论】在优化条件下,尤以超低温液氮保藏适合于去甲基万古霉素产生菌长期保藏。     

超低温冷冻对益智种子生理生化特性的影响

益智(Alpinia oxyphylla)是我国四大南药之一,其种子为顽拗性种子,不耐干燥和低温,无法常规保存。为解决益智种子长期稳定保存的问题,该研究以益智种子为材料,从种子含水量以及冷冻方式方面优化益智种子超低温保存方法,并对比液氮冷冻前后种子发芽率、α-淀粉酶活性、超氧化物歧化酶活性、过氧化物酶活性、脱氢酶活性、丙二醛含量等活力指标,分析液氮超低温冷冻对益智种子生理生化特性的影响。结果表明:直接液氮冷冻含水量13.92%~14.38%范围的种子是益智种子超低温保存的最佳条件。液氮冷冻后,随着超低温冷冻时间的延长,益智种子发芽率先由76.76%下降至52.5%,再上升至65%,最后下降并稳定在50%以上。其种子α-淀粉酶活性先下降后上升,然后又下降,最后上升并稳定至冷冻前的水平。丙二醛含量则是先上升后下降,最后趋于平稳状态。过氧化物酶活性是先下降,然后稳定在恒定水平。超氧化物歧化酶活性是随着冷冻时间的延长而持续上升,脱氢酶活性则是持续下降。以上结果说明,液氮冷冻时间对益智活力有一定的影响,但对种子有些性能具有一定的促进作用。无论是发芽率,还是生理生化指标,都不同程度表明液氮超低温保存益智种子是可行的。     

五种豆科药用植物种子超低温保存技术研究

以豆科药用植物降香檀、决明、含羞草、灰毛豆和猪屎豆的成熟种子为材料,探讨含水量对其发芽率的影响,以及超低温冷冻方式对种子超低温保存的影响。结果表明,降香檀、决明、猪屎豆和灰毛豆种子发芽率均随含水量的下降而从80%左右降至20%以下,而含羞草种子含水量低于10%时,其发芽率仍在75%以上。经超低温冷冻后,五种豆科药用植物种子发芽率较对照组均有显著差异;适宜的含水量下,种子经过超低温冷冻后其发芽率与对照组差异不显著,甚至高于对照组。三种冷冻方法中,玻璃化冷冻法更适合降香檀种子的超低温保存,缓慢冷冻法更适合猪屎豆种子的超低温保存,快速冷冻法适合于决明种子、灰毛豆种子和含羞草种子的超低温保存。由此可知,液氮超低温冷冻法保存降香檀等五种豆科药用植物种子是可行的。     

大鼠气管软骨和肌肉残余应变研究

提出两次性剪开方法, 即沿着垂直于气管软骨切线方向剪开软骨和肌肉的两个连接点, 由此分别得到气管软骨和肌肉的零应力状态, 并定义了表征零应力状态的软骨和肌肉张开角. 通过检测得到的气管软骨和肌肉无载荷和零应力状态的几何信息, 计算软骨和肌肉内、外壁残余应变, 以及相应的张开角. 结果表明软骨外壁处存在拉伸残余应变, 内壁处存在压缩残余应变; 肌肉外壁处存在拉伸残余应变, 靠近气管杈的气管环肌肉内壁处存在压缩残余应变, 其余气管环肌肉的内壁处存在拉伸残余应变, 这和血管等组织不同. 结果还表明, 软骨的残余应变要比肌肉的小很多, 往往只是肌肉的十分之一左右; 软骨张开角和肌肉残余应变呈正相关关系; 无论是残余应变的绝对值还是张开角, 都随着气管环轴向位置的下移而减小. 所得结果不仅表明气管是一周向和轴向极为非均匀的生物材料, 而且显示气管的残余应变情况与血管、食管等组织不同, 是深入研究气管重建的基础.     

大熊猫精液超低温冷冻的比较

对卧龙自然保护区大熊猫研究中心的9只雄性大熊猫电刺激采精,比较研究了稀释液中甘油含量、精液离心、不同稀释液和冷冻方法对大熊猫精液超低温冷冻保存后的活力、运动状态和顶体的影响。稀释液中甘油的含量为4％－5％较好,冻精解冻后的活力和顶体的正常率能保持鲜精的一半。离心和未离心的精液经超低温冷冻,解冻后的活力和运动状态都较接近。TEST和SFS两种稀释液的效果没有明显的差异。细管的冷冻过程较颗粒方便、快捷,时间容易控制,是一种较好的超低温冷冻精液的方法。     

水稻悬浮细胞的超低温保存研究

本研究分析了水稻悬浮细胞的生理状态和各种冷冻前处理等因素对超低温保存后细胞存活率的影响。结果表明,继代后培养３－５天,处于对数生长期的细胞,采用二步冷冻法,超低温保存后存活率最高,采用二步冷冻法,超低温保存后存活率最高。电镜超微结构观察显示,０．５ｍｏｌ／Ｌ,山梨醇预培养,１０％ＤＭＳＯ＋０．５ｍｏｌ／Ｌ山梨醇复合保护剂处理,液泡显著变小,数目明显减少,从而降低了细胞内自由水含量,数目明显减少,从     

真菌的冷冻扫描电镜观察

冷冻扫描电镜法是根据低温生物学原理,生物样品经过超低温处理后进行电镜观察的一种方法。经超低温冷冻固定的生物样品可保持其原有的形态特征和生物活性。样品内部水份在超低温(—150℃)下,即使在真空中升华速度     

园艺植物茎尖冷冻疗法脱毒的技术研究

超低温冷冻疗法是超低温保存技术在植物脱毒上的一个新的应用。由于其脱毒率高,操作简单,被认为是最有效脱除植物病毒的方法,为脱毒苗的生产开辟了一条新的途径。本文就超低温冷冻疗法脱毒的原理、操作程序、关键技术和在园艺植物上的最新研究进展进行综述,并对其今后的发展进行了展望。     

水稻悬浮细胞的超低温保存研究

本研究分析了水稻悬浮细胞的生理状态和各种冷冻前处理等因素对超低温保存后细胞存活率的影响。结果表明,继代后培养3—5天,处于对数生长期的细胞,采用二步冷冻法,超低温保存后存活率最高。电镜超微结构观察显示,0.5mol/L山梨醇预培养,10%DMSO 0.5mol/L山梨醇复合保护剂处理,液泡显著变小,数目明显减少,从而降低了细胞内自由水含量,增强细胞的抗冷冻能力。在上述合适的前处理和冷冻-化冻条件下,超低温保存水稻悬浮细胞的恢复生长率为58%,恢复生长的细胞转移到分化培养基上,可再生健壮绿苗, 移植到盆钵,在温室中长成正常结实的植株。     

Zero-stress states of arteries

The no-load configuration of a living organ is, in general, not the zero-stress state. The difference can be revealed by cutting up an unloaded organ to such an extent that the stress becomes zero in the tissue everywhere. For the aorta, it is shown that the configuration of the zero-stress state differs considerably from being a cylindrical tube. It is, in fact, an open sector with opening angles varying along the arterial tree. This article presents data on the zero-stress state in the arteries of the rat in normal condition.     

Effect of osmolarity on the zero-stress state and mechanical properties of aorta

Some pathological conditions may affect osmolarity, which can impact cell, tissue, and organ volume. The hypothesis of this study is that changes in osmolarity affect the zero-stress state and mechanical properties of the aorta. To test this hypothesis, a segment of mouse abdominal aorta was cannulated in vivo and mechanically distended by perfusion of physiological salt (NaCl) solutions with graded osmolarities from 145 to 562 mosM. The mechanical (circumferential stress, strain, and elastic modulus) and morphological (wall thickness and wall area) parameters in the loaded state were determined. To determine the osmolarity-induced changes of zero-stress state, the opening angle was observed by immersion of the sectors of mouse, rat, and pig thoracic aorta in NaCl solution with different osmolarities. Wall volume and tissue water content of the rings were also recorded at different osmolarities. Our results show that acute aortic swelling due to low osmolarity leads to an increase in wall thickness and area, a change in the stress-strain relationship, and an increase in the elastic modulus (stiffness) in mouse aorta. The opening angle, wall volume, and water content decreased significantly with increase in osmolarity. These findings suggest that acute aortic swelling and shrinking result in immediate mechanical changes in the aorta. Osmotic pressure-induced changes in the zero-stress state may serve to regulate mechanical homeostasis.     

Morphology and stress-strain properties along the small intestine in the rat

The stress-strain relationship is determined by the inherent mechanical properties of the intestinal wall, the geometric configurations, the loading conditions and the zero-stress state of the segment. The purpose of this project was to provide morphometric and biomechanical data for rat duodenum, jejunum and ileum. The circumferential strains were referenced to the zero-stress state. Large morphometric variations were found along the small intestine with an increase in the outer circumferential length and luminal area and a decrease in wall thickness in distal direction. The serosal residual strain was tensile and decreased in distal direction (P < 0.05). The mucosal residual strain was compressive and the absolute value decreased in distal direction (P < 0.001). The stress-strain experiments showed that the duodenum was stiffest. All segments were stiffest in longitudinal direction (P < 0.05). In conclusion, axial variation in morphometric and biomechanical properties was found in the small intestine. The zero-stress state must be considered in future biomechanical studies in the gastrointestinal tract.     

The zero-stress state of rat veins and vena cava

The zero-stress state of a vein is, like that of an artery, not a closed cylindrical tube, but is a series of segments whose cross-sections are open sectors. An opening angle of each sector is defined as the angle subtended between two radii joining the midpoint of the inner wall to the tips of the inner wall. Data on the opening angles (mean +/- standard deviation) of the veins and vena cava of the rat are presented. For the superior vena cava and subclavian, jugular, facial, renal, common iliac, saphenous, and plantar veins, the opening angle varies in the range of 25 to 75 deg. The inferior vena cava (below the heart), however, has noncircular, nonaxisymmetric cross-sections, a curved axis, and a rapid longitudinal variation of its "diameter"; its zero-stress state is not circular sectors; but the opening angle is still a useful characterization. The mean opening angle of the interior vena cava varies in the range of 40 to 150 deg in the thoracic portion, and 75 to 130 deg in the abdominal portion, with the larger values occurring about the middle of each portion. There are considerable length, diameter reductions, and wall thickening of the vena cava from the homeostatic state to the no-load state in vitro. Physically, the zero-stress state is the basis of the stress analysis of blood vessels. The change of opening angle is a convenient parameter to characterize any nonuniform remodeling of the vessel wall due to changes in physical stress or chemical environment.(ABSTRACT TRUNCATED AT 250 WORDS)     

Duration of no-load state affects opening angle of porcine coronary arteries

The zero-stress state of a blood vessel has been extensively studied because it is the reference state for which all calculations of intramural stress and strain must be based. It has also been found to reflect nonuniformity in growth and remodeling in response to chemical or physical changes. The zero-stress state can be characterized by an opening angle, defined as the angle subtended by two radii connecting the midpoint of the inner wall. All prior studies documented the zero-stress state or opening angle with no regard to duration of the no-load state. Our hypotheses were that, given the viscoelastic properties of blood vessels, the zero-stress state may have "memory" of prior circumferential and axial loading, i.e., duration of the no-load state influences opening angle. To test these hypotheses, we considered ring pairs of porcine coronary arteries to examine the effect of duration in the no-load state after circumferential distension. Our results show a significant reduction in opening angle as duration of the no-load state increases, i.e., vessels that are reduced to the zero-stress state directly from the loaded state attain much larger opening angles at 30 min after the radial cut than rings that are in the no-load state for various durations. To examine the effect of axial loading, we found similar reductions in opening angle with duration in the no-load from the in situ state, albeit the effect was significantly smaller than that of circumferential loading. Hence, we found that the zero-stress state has memory of both circumferential and axial loading. These results are important for understanding viscoelastic properties of coronary arteries, interpretation of the enormous data on the opening angle and strain in the literature, and standardization of future measurements on the zero-stress state.     

Regional distribution of axial strain and circumferential residual strain in the layered rabbit oesophagus

The oesophagus is subjected to large axial strains in vivo and the zero-stress state is not a closed cylinder but an open circular cylindrical sector. The closed cylinder with no external loads applied is called the no-load state and residual strain is the difference in strain between the no-load state and zero-stress state. To understand oesophageal physiology and pathophysiology, it is necessary to know the distribution of axial strain, the zero-stress state, the stress-strain relations of oesophageal tissue, and the changes of these states and relationships due to biological remodeling of the tissue under stress. This study is addressed to such biomechanical properties in normal rabbits. The oesophagi were marked on the surface in vivo, photographed, excised (in vitro state), photographed again, and sectioned into rings (no-load state) in an organ bath containing calcium-free Kreb's solution with dextran and EGTA added. The rings were cut radially to obtain the zero-stress state for the non-separated wall and further dissected to separate the muscle and submucosa layers. Equilibrium was awaited for 30min in each state and the specimens were photographed in no-load and the zero-stress states. The oesophageal length, circumferences, layer thicknesses and areas, and openings angle were measured from the digitised images. The oesophagus shortened axially by 35% after excision. The in vivo axial strain showed a significant variation with the highest values in the mid-oesophagus (p<0.001). Luminal area, circumferences, and wall and layer thicknesses and areas varied in axial direction (in all tests p<0.05). The residual strain was compressive at the mucosal surface and tensile at the serosal surface. The dissection studies demonstrated shear forces between the two layers in the non-separated wall in the no-load and zero-stress states. In conclusion, our data show significant axial variation in passive morphometric and biomechanical properties of the oesophagus. The oesophagus is a layered composite structure with nonlinear and anisotropic mechanical behaviour.     

Effect of Danshen on the Zero-Stress State of Rat's Abdominal Aorta

The objective of our study was to study the effect of danshen, a Chinese herbal medicine known to prevent hypertension, on the zero-stress state of rat's abdominal aorta. The zero-stress state of a blood vessel represents the release of residual stress on the vessel wall, and is the basic configuration of blood vessel affected solely by intrinsic parameters. At the in vivo state, the rat's abdominal aorta was subjected to blood pressure and flow and longitudinal stress. After dissecting from the abdominal aorta, the aortic specimens were cut into small rings at no-load state, in which the internal pressure, external pressure, and longitudinal stress in a short ring-shaped segment were all zero; by cutting radially to release the residual stress in the wall, the vessel ring opened up into a sector quickly, and the sector's configuration would not change at 20 min after cutting and was defined as the zero-stress state of a blood vessel, which was characterized by its residual strain and opening angle. Then aqueous extract of danshen prepared with methanol was added in the Krebs solution, and the changes of the aorta's zero-stress state were monitored by taking photos routinely for analysis to determine the opening angle and residual strain. Additionally, other sets of samples were tested in a Norepinephrine-Krebs solution as positive control or a Krebs solution as negative control, respectively. It was demonstrated that the zero-stress state of rat's abdominal aorta was affected by danshen extract and norepinephrine in two different patterns, while the Krebs solution did not have similar effects. The present work provides a new approach to study the anti-hypertension effect and mechanism of danshen.     

自发性高血压大鼠四氢生物碟呤治疗后动脉的结构及力学改变

目的：探讨长期四氢生物喋呤（BH4）治疗对自发性高血压大鼠（SHR）血管形态及血管力学性质的影响;方法：选用4周龄雄性SHR36只,随机分为实验组和对照组,每组18只。实验组每周2次腹腔注射BH420mg／kg,对照组注射等容量生理盐水,于实验第4、16和26周龄时各取6只测量动脉收缩压（SBP）,并使用计算机图像分析的方法分别测量主动脉血管零应力状态张开角、压力-直径关系及肠系膜动脉血管的壁／腔比值。结果：至BH4治疗后的第16和26周龄,SHR的SBP明显降低（P〈0．01）;实验组SHR胸主动脉张开角显著减小（P〈0．01）,压力-直径（P-D）关系曲线上移;实验组肠系膜动脉三级分支血管壁／腔（W／L）值减小（P〈0．05）。结论：BH4可以减弱由于长期高血压所导致的血管肥厚和管腔狭窄,恢复血管弹性。     

Biomechanical and morphological properties in rat large intestine

Intestinal stress-strain distributions are important determinants of intestinal function and are determined by the mechanical properties of the intestinal wall, the physiological loading conditions and the zero-stress state of the intestine. In this study the distribution of morphometric measures, residual circumferential strains and stress-strain relationships along the rat large intestine were determined in vitro. Segments from four parts of the large intestine were excised, closed at both ends, and inflated with pressures up to 2kPa. The outer diameter and length were measured. The zero-stress state was obtained by cutting rings of large intestine radially. The geometric configuration at the zero-stress state is of fundamental importance because it is the basic state with respect to which the physical stresses and strains are defined. The outer and inner circumferences, wall thickness and opening angle were measured from digitised images. Subsequently, residual strain and stress-strain distributions were calculated. The wall thickness and wall thickness-to-circumference ratio increased in the distal direction. The opening angle varied between approximately 40 and approximately 125 degrees with the highest values in the beginning of proximal colon (F=1.739, P<0.05). The residual strain at the inner surface was negative indicating that the mucosa-submucosal layers of the large intestine in no-load state are in compression. The four segments showed stress-strain distributions that were exponential. All segments were stiffer in longitudinal direction than in the circumferential direction (P<0.05). The transverse colon seemed stiffest both in the circumferential and longitudinal directions. In conclusion, significant variations were found in morphometric and biomechanical properties along the large intestine. The circumferential residual strains and passive elastic properties must be taken into account in studies of physiological problems in which the stress and strain are important, e.g. large intestinal bolus transport function.     

Experimental investigation of collagen waviness and orientation in the arterial adventitia using confocal laser scanning microscopy

Mechanical properties of the adventitia are largely determined by the organization of collagen fibers. Measurements on the waviness and orientation of collagen, particularly at the zero-stress state, are necessary to relate the structural organization of collagen to the mechanical response of the adventitia. Using the fluorescence collagen marker CNA38-OG488 and confocal laser scanning microscopy, we imaged collagen fibers in the adventitia of rabbit common carotid arteries ex vivo. The arteries were cut open along their longitudinal axes to get the zero-stress state. We used semi-manual and automatic techniques to measure parameters related to the waviness and orientation of fibers. Our results showed that the straightness parameter (defined as the ratio between the distances of endpoints of a fiber to its length) was distributed with a beta distribution (mean value 0.72, variance 0.028) and did not depend on the mean angle orientation of fibers. Local angular density distributions revealed four axially symmetric families of fibers with mean directions of 0°, 90°, 43° and ?43°, with respect to the axial direction of the artery, and corresponding circular standard deviations of 40°, 47°, 37° and 37°. The distribution of local orientations was shifted to the circumferential direction when measured in arteries at the zero-load state (intact), as compared to arteries at the zero-stress state (cut-open). Information on collagen fiber waviness and orientation, such as obtained in this study, could be used to develop structural models of the adventitia, providing better means for analyzing and understanding the mechanical properties of vascular wall.