Some Observations on Glass-Knife Making

The yield of usable knife edge per Me (for thin sectioning) was markedly increased when glass knives were made at an included angle of 55° rather than the customary 45deg;. A large number of measurements of edge check marks made with a routine light scattering method as well as observations made on a smaller number of test sections with the electron microscope indicated the superiority of 55° knives. Knives were made with both taped pliers and an LKB Knifemaker. Knives were graded by methods easily applied in any biological electron microscope laboratory. Depending on the mode of fracture, the yield of knives having more than 33% of their edges free of check marks was 30 to 100 times greater at 55° than 45°.     

Steam explosion of woody hemp chènevotte

This paper concerns the morphology of hemp woody core cells, investigated by optical and scanning electron microscopy, and the chemical analysis of the hemp cells. Steam explosion was investigated as a pre-treatment step for woody hemp ‘chènevotte’, with the aim of optimizing the separation and delignification of woody fibres.

In this study, we report the results of five experiments performed on ‘chènevotte’ samples impregnated in acid solution (0.1% w/w H₂SO₄) and steamed at 200, 210, 220, 230 and 240°C for 180 s. The effect of process temperatures on the woody hemp core after acidic impregnation was followed by optical and scanning electron microscopy, by assessment of the chemical composition, and by evolution of the average degree of polymerization (DPv) values of the purified wood fibres.

We found that treatment at 200 and 210°C led to samples that were difficult to delignify because the destructuring and disintegration of lignocellulosic materials were insufficient. A temperature of the order of 220–230°C is required to obtain well-separated fibres. However, at a temperature of 240°C, degradation and fibre damage were noted.     

Self-propagating calciferous particles detected in a human cell line Kasumi-6 (JCRB 1024)

Summary Tiny particles were found in the medium in the presence of the human leukemia cell line Kasumi-6. The particles were separated from human cells by filtration and incubated in RPMI1640 supplemented with 10% fetal calf serum at 37 C. The particles increased in number very slowly in the liquid medium but did not reveal any biological activity. Transmission electron microscopy of the particles showed a spheroid or ovoid shape in ultrathin section. No specific polypeptides from the purified particles were detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), except for bovine fetuin that adsorbed to the surface of the particles. X-ray diffractometry as well as Fourier transform infrared spectrometry suggested the particles consisted of hydroxyapatite. The mechanism of self-propagation of the hydroxyapatite particles in liquid medium is currently unknown. This type of particle has been overlooked for a long period because it is noncultivable. It will be necessary to examine its biological effects to the cultured cells.     

A theoretical approach to the relationship between wettability and surface microstructures of epidermal cells and structured cuticles of flower petals

Background and Aims The epidermal surface of a flower petal is composed of convex cells covered with a structured cuticle, and the roughness of the surface is related to the wettability of the petal. If the surface remains wet for an excessive amount of time the attractiveness of the petal to floral visitors may be impaired, and adhesion of pathogens may be promoted. However, it remains unclear how the epidermal cells and structured cuticle contribute to surface wettability of a petal.Methods By considering the additive effects of the epidermal cells and structured cuticle on petal wettability, a thermodynamic model was developed to predict the wetting mode and contact angle of a water droplet at a minimum free energy. Quantitative relationships between petal wettability and the geometries of the epidermal cells and the structured cuticle were then estimated. Measurements of contact angles and anatomical traits of petals were made on seven herbaceous species commonly found in alpine habitats in eastern Nepal, and the measured wettability values were compared with those predicted by the model using the measured geometries of the epidermal cells and structured cuticles.Key Results The model indicated that surface wettability depends on the height and interval between cuticular steps, and on a height-to-width ratio for epidermal cells if a thick hydrophobic cuticle layer covers the surface. For a petal epidermis consisting of lenticular cells, a repellent surface results when the cuticular step height is greater than 0·85 µm and the height-to-width ratio of the epidermal cells is greater than 0·3. For an epidermis consisting of papillate cells, a height-to-width ratio of greater than 1·1 produces a repellent surface. In contrast, if the surface is covered with a thin cuticle layer, the petal is highly wettable (hydrophilic) irrespective of the roughness of the surface. These predictions were supported by the measurements of petal wettability made on flowers of alpine species.Conclusions The results indicate that surface roughness caused by epidermal cells and a structured cuticle produces a wide range of petal wettability, and that this can be successfully modelled using a thermodynamic approach.     

Surface Wettability and Chemistry of Ozone Perfusion Processed Porous Collagen Scaffold

Crosslinking treatment of collagen has often been used to improve the biological stability and mechanical properties of 3D porous collagen scaffolds. However, accompanying these improvements, the collagen fibril surface becomes hydrophobic nature resulting in a reduced surface wettability. The wetting of the collagen fibril by culture medium is reduced and it is difficult for the medium to diffuse into the 3D structure of a porous collagen scaffold. This paper reports a “perfusion processing” strategy using ozone to improve the surface wettability of chemical crosslinked collagen scaffolds. Surface wettability, surface composition and biological stability were analyzed to evaluate the effectiveness of this surface processing strategy. It was observed that ozone perfusion processing improved surface wettability for both exterior and interior surfaces of the porous 3D collagen scaffold. The improvement in wettability is attributed to the incorporation of oxygen-containing functional groups onto the surface of the collagen fibrils, as confirmed by X-ray Photoelectron Spectroscopy (XPS) analysis. This leads to a significant improvement in water taking capability without compromising the bulk biological stability and mechanical properties, and confirms that ozone perfusion processing is an effective tool to modify the wettability both for interior and exterior surfaces throughout the scaffold.     

Directional dependence of hydroxyapatite-collagen interactions on mechanics of collagen

Bone is a biological nanocomposite composed primarily of collagen and hydroxyapatite. The collagen molecules self-assemble to from a structure known as a fibril that comprises of about 85–95% of the total bone protein. In a fibril, the molecular level interactions at the interface between molecular collagen and hydroxyapatite nanocrystals have a significant role on its mechanical response. In this study, we have used molecular dynamics and steered molecular dynamics to study directional dependence of deformation response of collagen with respect to the hydroxyapatite surface. We have also studied mechanical response of collagen in the proximity of (0 0 0 1) and (1 0 1¯0) surfaces of hydroxyapatite. Our simulations indicate that the mechanics of collagen pulled in different directions with respect to hydroxyapatite is significantly different. Similar results were obtained for collagen pulled in the proximity of different crystallographic surfaces of hydroxyapatite.     

Measurements of nonhomogeneous, directional mechanical properties of articular cartilage in tension

The purpose of this investigation is to develop an accurate experimental procedure to measure the elastic properties of articular cartilage in uniaxial tension. Standardized, dumbbell shaped specimens, 250–325 μm thick, were taken from the surface, middle, and deep zones of the articular cartilage at 0°, 45°, and 90° from axis of the cleavage line pattern for the study of the zonal and directional properties of articular cartilage. A total of 75 specimens were tested to failure in this study. The use of a video dimensional analyzer system in this study makes accurate monitoring of the deformation of articular cartilage specimens possible. Nonlinear stress-strain relationships of the articular cartilage samples were mathematically approximated by exponential law similar to Fung (1967). Higher stiffness for the 0° specimens in the surface and middle zones was found. The experimental findings are in general agreement with the interpretations of low magnification scanning electron microscopy.     

The microbiology of pine bark composting: An Electron-microscope and physiological study

An electron microscope study was conducted on samples of pine bark taken from stacks during consecutive stages of composting. It was found using scanning electron microscopy (SEM) that bacteria, actinomycetes and fungi were present in relatively low numbers on the bark surface before composting was initiated. After addition of urea and water to bark heaps, microbial numbers rose, particularly the bacterial fraction. A large number of actinomycetes were seen below the surface of the bark as composting progressed. Transmission electron microscopy (TEM) of bark in the late stages of composting demonstrated the presence of a variety of microbes within the bark cells. The microorganisms were seen, using SEM, to be degrading the surface of the bark chips, and, using TEM, to be attached to the lignified cell walls. Physiological studies on bacteria isolated at different stages of composting showed they had a number of enzymes such as carboxymethyl cellulase that could aid in the degradation of pine bark. The isolates consisted of Gram-negative and Gram-positive strains, some of which were spore formers. Most of the isolates, including some Gram-negative non-sporing bacteria, were able to grow over a wide range of temperatures from 30 to 60°C, and, in some cases, 70°C.     

羟基磷灰石/柞蚕丝素（HA/TSF骨仿生纳米纤维的生物学性能研究

目的：柞蚕丝素（tussah silk fibroin,TSF）和羟基磷灰石（hydroxyapatite,HA）均具有良好的生物活性和生物相容性,是组织工程研究的热点i,但结构单一及微米级的材料所表现出的性能简单,不能满足人们对生物材料支架性能的要求,本课题将两者按不同比例进行复合,探讨不同皮芯比例羟基磷灰石／柞蚕丝素（HA／TSF）的骨仿生纳米纤维的生物学性能。方法：首先利用同轴静电纺丝技术,以TSF水溶液为皮,HA水溶液为芯,制备不同皮芯比例的HA／TSF骨仿生纳米纤维,然后将人成骨肉瘤细胞（MG-63）种植在不同皮芯比例的HA／TSF纳米纤维上。在不同的时间点分别通过倒置显微镜、扫描电镜观察细胞形态学变化;通过四甲基偶氮噻唑蓝比色（Four methyl azo thiazole blue colorimetric, MTT）法、碱性磷酸酶（alkaline phosphatase,ALP）活性检测法观察细胞在材料表面的增殖和分化,从多角度来评价材料的生物学性能。结果：通过形态学观察,SEM观察以及MTT检测,发现除空白对照组外,各组样品均显示良好的生物相容性,均能促进细胞的黏附、增殖,尤以HA／TSF为2：1时最明显;通过MG-63细胞的ALP活性检测,发现当HA／TSF比例为2：1时,最能促进细胞ALP活性的表达,有利于诱导成骨细胞的分化。结论：皮芯结构的HA／TSF骨仿生纳米纤维具有良好的生物学性能,且二者在自然界来源丰富,价格便宜,为临床骨组织缺损修复的应用奠定了一定的实验基础     

Surface and intracellular localization of concanavalin A in human lymphocytes

Normal human lymphocytes were treated at +4 °C with concanavalin A and subsequently washed. The cells were then incubated for various periods at +37 °C in a culture medium and the fate of the agglutinin was followed by an electron microscopic stain specific for concanavalin A. At zero incubation time, a positive reaction was noted on the entire cell membrane and on numerous pinocytic vesicles; 80% of the lymphocytes were stained. Within 15 min of incubation, the cell surface appeared discontinuously labelled while all the intracytoplasmic vesicles were strongly positive. After 2 h of incubation, the cell surface was almost free of label and positive vesicles were found to be concentrated at one pole of the cell. After 3 h of incubation, no label was found on the cell membrane; instead, large vesicles communicating with the cell membrane contained labelled material.     

The role played by modified bioinspired surfaces in interfacial properties of biomaterials

The success of a biomaterial relies on an appropriate interaction between the surface of that biomaterial and the surrounding environment; more specifically, the success of a biomaterial depends on how fluids, proteins, and cells interact with the foreign material. For this reason, the surface properties of biomaterial, such as composition, charge, wettability, and roughness, must be optimized for a desired application to be achieved. In this review we highlight different bioinspired approaches that are used to manipulate and fine-tune the interfacial properties of biomaterials. Inspired by noteworthy natural processes, researchers have developed materials with a functional anatomy that range from hierarchical hybrid structures to self-cleaning interfaces. In this review we focus on (1) the creation of particles and modified surfaces inspired by the structure and composition of biogenic mineralized tissues, (2) the development of biofunctional coatings, (3) materials inspired by biomembranes and proteins, and (4) the design of superwettable materials. Our intention is to point out different bioinspired methodologies that have been used to design materials for biomedical applications and to discuss how interfacial properties modified by manipulation of these materials determine their final biological response. Our objective is to present future research directions and to highlight the potential of bioinspired materials. We hope this review will provide an understanding of the interplay between interfacial properties and biological response so that successful biomaterials can be achieved.     

Microwave Irradiation as a Generator of Heat for Histological Fixation

The kitchen appliance known as the “radar oven” generates heat quickly in materials containing water. Protoplasm exposed to the irradiation can thus be denatured. The amount of heat generated is a function of the time of exposure and the intensity of the irradiation, and the size and specific heat of the tissue or organism being irradiated. But docs such heating have applicabiity to histological technique? One of four carcas temperaturea (approximately 60°, 70°, 77°, and 85 C) was generated in anaesthetized, adult hairless mice of both sexes. “Control” animals were not irradiated. Specimens of liver, kidney, lung, and (from males) testis were taken from the five groups; the tissue spedmens were dehydrated in tetrahydrofuran, embedded in paraffin, sectioned at 9 μm, and stained with hematoxylin and eosin. The preparations were suitable for histological examination. Each organ had an optimum temperature for histological fixation under the conditions of this experiment: liver, ∼70°; kidney, ∼77°; lung, ∼77°; and testis, ∼85 C. Heat fixation by microwave irradiation also shows some applicability to electron microscopical studies and to investigations of the blood vascular arrangements of organs.     

Biomimetic mineralization induced by fibrils of polymers derived from a bile acid

A polymer containing bile acid pendant groups was prepared by free-radical polymerization of the 3alpha-methacrylate derivative of cholic acid. The polymer formed fibrils of about 1 nm in diameter in aqueous media and further assembled into bundles or lamella plates, as observed by transmission electron microscopy. After immersing the fibrils in simulated body fluid with ion concentrations equivalent to those in human plasma, plate-like crystals formed on the surface of the fibril assembly. The diffraction pattern corresponding to the (001) plane of hydroxyapatite was identified by transmission electron microscopy and selected area electron diffraction. The plate-like, single crystal hydroxyapatite formed on such a polymeric assembly may be useful in the matrix design for biomimetic mineralization and in the development of scaffold materials for hard tissue engineering.     

Adhesion of cultured mammalian central nervous system neurons to flame-modified hydrophobic surfaces

Summary Surface wettability is an excellent indicator of the ability of cells to adhere to a culture substrate. We have determined that brief exposure of a hydrophobic culture surface to a propane flame may increase wettability more than 1200% via the deposition of ionic combustion products. Previously nonadherent mouse spinal cord cells will adhere to and differentiate morphologically on a hydrophobic surface after flaming. Central nervous system cells remain adhered to flamed surfaces for periods of 2 mo. or longer and demonstrate spontaneous electrical activity during that time. Secondary modification of a flamed surface with polylysine further enhances the strength of single cell adhesion, thereby retarding mobility and promoting neurite extension. Flaming also enhances the wettability of common culture materials such as glass and polystyrene, as well as metal. Flaming of hydrophobic substrates through masks permits creation of discrete adhesion islands and patterns which may be used for a variety of investigations requiring maintenance of different cell types in separate regions of a culture surface. This research was supported by U.S. Public Health Service grant 2 RO1 NS 15167.     

Variations in the activity of fatty ACYL-CoA desaturases and electron-transport components in Tetrahymena microsomes with temperature and age of culture

1. 1.|Alterations in the fatty acid composition of microsomes were most marked in the exponential phase of both 39.5- or 15°C- grown Tetrahymena pyriformis NT-1.

2. 2.|Activities of palmitoyl-CoA and stearoyl-CoA desaturases were lower in 15°C cells than in 39.5°C cells, while the activity of oleoyl-CoA desaturase was higher in 15°C cells.

3. 3.|Activities of the terminal component of the desaturation system as well as all three desaturases (palmitoyl-CoA, stearoyl-CoA, oleoyl-CoA) were higher in the exponential phase than in the stationary phase for cells grown at both temperatures.

4. 4.|NAD(P)H-cytochrome c reductase activity and cytochrome b₅ content were reduced whereas NADH-ferricyanide reductase activity was increased in the stationary phase at both 39.5 and 15°C.

Cold shock during liquid production increases storage shelf-life of Cryptococcus nodaensis OH 182.9 after air-drying

Fermentation, formulation and drying studies are necessary and important in order to simplify production, transportation, storage and application of biocontrol agents. Air-drying is a convenient and economical drying method for developing microbial biocontrol products. Experiments were designed to determine the effect of temperature shock during liquid cultivation on cell survival of a Fusarium head blight biocontrol agent Cryptococcus nodaensis OH 182.9 after air-drying. OH 182.9 cultures were grown at various temperatures in semi-defined complete liquid media, with cultures grown at 25°C for 48 h serving as the standard control culture condition. Harvested cultures were mixed with 10% diatomaceous earth (DE), vacuum filtered, air dried for 20 h at 60-70% RH, and stored at 4°C. In general, cells grown at 25°C for 20 h followed by cultivation at 15°C for 28 h survived air-drying better than control cells. The survival of cells subjected to heat shock at 31°C generally did not differ from control cells regardless of whether heat shock was applied at the late exponential or early stationary stage of growth. In another experiment designed to optimize the effect of cold temperatures during cultivation on subsequent survival of air-dried cells in DE at 4°C and room temperature (25°C), prolonged (28 h) cold shock at 10 and 15°C after incubation at 25°C for 20 h enhanced the storage stability (shelf-life) of a DE-formulated OH 182.9 product. In greenhouse tests, air-dried cells of OH 182.9 stored for 6 weeks at 4°C maintained a higher biocontrol efficacy than cells stored for 6 weeks at 25°C.     

Micro precipitation of lead on the surface of crab shell particles

Crab shell particles were used as a biosorbent to remove lead from aqueous solutions. The equilibrium isotherm showed that crab shell particles took up lead to the extent of 1300 mg Pb g⁻¹ crab shell. The optimum pH range for maximum lead removal was increased to 5·5–11·0 compared to the shell-free control pH of 8·5–11·0. pH values of solutions with crab shell material added were increased spontaneously to about 10 as a result of the CaCO₃ present, which formed complexes with lead according to pH. Electron spectroscopy, Fourier transform infrared spectrometry, scanning electron microscopy and X-ray diffraction results confirmed that -NHCOCH₃ and CO₃² were involved in binding of lead. In addition, the removal of lead occurred mainly through dissolution of CaCO₃ followed by precipitation of Pb₃(CO₃)₂(OH)₂ and PbCO₃ near the surface of crab shell. Micro precipitates formed were then adsorbed to the chitin on the surface of the crab shell particles.     

Effect of Temperature on Development and Population Growth of Acarophenax lacunatus (Cross & Krantz) (Prostigmata: Acarophenacidae) on Rhyzopertha dominica (F.) (Coleoptera: Bostrichidae)

The parasitic mite Acarophenax lacunatus kills the eggs upon which it feeds and seems to have potential as a biological control agent of stored grain pests. The lack of biological studies on this mite species led to the present study carried out in laboratory conditions at eight different temperatures (ranging from 20 to 41°C) and 60% relative humidity using Rhyzopertha dominica as host. The higher the temperature, the faster: (1) the attachment of female mites to the host egg (varying from 1 to 5 h); (2) the increase in body size of physogastric females (about twice faster at 40°C than at 20°C); and (3) the generation time (ranging from 40 to 220 h). In addition, the higher the temperature, the shorter the maximum female longevity (ranging from about 75 to 300 h). The two estimated temperature thresholds for development of A. lacunatus on R. dominica were 18 and 40°C. The average number of female and male offspring per gravid mite were 12.8 and 1.0, respectively, with sex ratios (females/total) ranging from 0.91 to 0.94 (maximum at 30°C). The net reproductive rate and intrinsic rate of increase also presented maximum values at 30°C (12.1 and 0.04, respectively).     

A temperature-sensitive mutant of cultured mouse cells defective in chromosome condensation

A temperature-sensitive mutant, designated ts85, was isolated from a mouse mammary carcinoma cell line, FM3A. The ts85 cells grew at 33 °C (permissive temperature) with a doubling time of 18 h, which was almost the same as with wild-type cells, whereas the cell number scarcely increased at all at 39 °C (non-permissive temperature). When the ts85 cells were shifted from 33 to 39 °C, their DNA synthesis fell to below 1% of the initial value in 14 h. RNA or protein synthesis, however, was maintained at the initial levels for at least 14 h at 39 °C. Cytofluorometric analysis of asynchronous cultures and studies with synchronous cultures suggested that the bulk of the cells cultured at 39 °C for 12–18 h were arrested in late S and G2 phases. Electron microscopic observations revealed that chromatin was abnormally condensed into fragmented and compact forms, particularly around nucleoli, in about 80% of cells of an asynchronous culture incubated at 39 °C for 16 h. Cells in mitosis were not detected in such cultures and nuclear membrane and nucleoli were still intact. Such abnormal chromosome condensation was not observed in the ts85 cells at 33 °C or in wild-type cells at either temperature. Since these findings suggest that a ts gene product of ts85 cells is necessary for chromosome condensation, ts85 cells may represent a useful tool for establishing the mechanisms of chromosome condensation. The interrelationship between abnormal chromosome condensation and reduction in DNA synthesis of the ts85 cells is discussed.     

Molecular and granular characteristics of corn starch modified by HCl-methanol at different temperatures

Native corn starch was hydrolyzed with 0.36% HCl in methanol at 25 and 45 °C for periods of time up to 240 h. The action of acid penetration and hydrolysis was investigated by confocal laser scanning microscopy (CLSM), scanning electron microscopy (SEM), high-performance anion-exchange chromatography (HPAEC) and high-performance size-exclusion chromatography (HPSEC) equipped with viscometry, right-angle laser light scattering (RALLS) and refractive index (RI) detectors. Corn starch hydrolyzed at 45 °C for 240 h showed strong intensity of APTS (8-amino-1,3,6-pyrenetrisulfonic acid) fluorescence and sharp growth ring structure. Exocorrosion over the surface of corn starch was only observed on the corn starch hydrolyzed at 25 °C for 240 h and observed on all corn starch hydrolyzed at 45 °C. The M_w and R_h of acid-hydrolyzed corn starch decreased with increasing the degree of hydrolysis. The acid hydrolysis rate in methanol of corn starch was mainly dependent on the temperature, which dominated the penetration efficiency of acid.