Cell growth and death rates as factors in the long-term performance, modeling, and design of immobilized cell reactors

The viable fraction of immobilized cells in a bioreactor may be critical in predicting long-term or steady-state reactor performance. The assumption of near 100% viable cells in a bioreactor may not be valid for portions of immobilized cell reactors (ICRs) characterized by conditions resulting in appreciable death rates. A mathematical model of an adsorbed cell type ICR is presented in which a steady-state viable cell fraction is predicted, based on the assumptions of no cell accumulation in the reactor and a random loss of cells from the reactor. Data on cell death rates, cell growth rates, and productivity rates as functions of temperature, substrate, and ethanol concentration for the lactose utilizing yeast K. fragillis were incorporated into this model. The steady-state reactor viable cell fraction as predicted by this model is a strong function of both temperature and ethanol concentration. For example, a stable 20% viable fraction of the immobilized cells is predicted in ICR locations experiencing continuous conditions of either 30 g/L ethanol at 40 degrees C, or 95 g/L ethanol at 25 degrees C. Steady-state ICR "plug flow" concentration profiles and column productivities are predicted at three operating temperatures, 20, 30, and 40 degrees C using two different models for ethanol inhibition of productivity. These profiles suggest that the reactor operating temperature should be low if higher outlet ethanol concentrations are desired. Three reactor design strategies are presented to maximize the viable cell fraction and improve long-term ethanol productivity in ICR's: (1) reducing outlet ethanol concentrations, (2) rotating segments of an ICR between high and low ethanol environments, and (3) simultaneous removal of the ethanol produced from the reactor as it is formed.     

Oil Blue Na as A Stain for Rubber in Sectioned or Ground Plant Tissues

Oil blue NA (Calco), a stain which colors rubber bright blue, has been used effectively in studying the distribution of rubber in several plant species. Fresh or fixed sections are cut, bleached with Javelle water or NaOCl solution, treated with 9% KOH in 95% ethanol, washed with several changes of water and finally with 95% ethanol, and stained with 0.05% oil blue NA in 70% ethanol. Sections are rinsed in 50%' ethanol, placed in 40% glycerin, and mounted in glycerin jelly.

For the detection of changes in the distribution and character of rubber in milled or ground tissues, much the same staining procedure is followed. The stained tissues usually are examined and dissected under a stereoscopic microscope, a procedure which permits rubber to be recognized by both its staining reaction and by a more specific property, elastic elongation.

A microscopic technic is presented whereby it is possible to determine approximately the relative proportion of dispersed and coagulated rubber latex in unstained tissues.     

Viability of Candida shehatae in D-xylose fermentations with added ethanol

Ethanol was added at concentrations of 25 and 50 g/L to active cultures of Canida shehatae under oxygen-limited (fermentative) conditions. Added ethanol completely inhibited grwoth and fermentation of D-xylose by C. shehatae. Cultures with added ethanol rapidly declined in cell viability as measured by plate counts and methylene blue staining. The rate of decline in cell viability was dependent on the amount of added ethanol. Over the course of the fermentation, cell viability, as measured by plate counts, was significantly lower in all experiments (with or without ethanol addition) compared with the viability measurements by methylene blue staining. Thus, data from the plate counts provided a more sensitive measure of the toxic effects of added ethanol and long-term anaerobiosis on C. shehatae growth/fermentation. Mean cell volume and total cell volume declined in fermentations with added ethanol. (c) 1992 John Wiley & Sons, Inc.     

Proliferation and death of cultured fetal neocortical neurons: effects of ethanol on the dynamics of cell growth

Neuronal number in the mature CNS is determined by the balance of cell proliferation and death. The effects of ethanol on cell proliferation and death were examined in primary cultures of neocortical neurons derived from 16-day-old rat fetuses. The cells were treated with ethanol (0 or 400 mg/dl) and examined for (1) immunohistochemical identity, (2) cell cycle kinetics using a cumulative bromodeoxyuridine labeling technique, (3) viable cell number via a trypan blue assay, and (4) the incidence of cell death with terminal deoxy-nucleotidyl transferase-mediated dUTP nick end labeling (TUNEL) and caspase 3 immunhistochemistry. After two days in culture, most (>85%) cells expressed a neuron-specific antigen(s) whether or not ethanol was added to the culture medium. Ethanol affected the proliferation of the cultured cells, e.g., the length of the cell cycle was greater in the ethanol-treated cells than in controls. The number of trypan blue-negative (viable) cells was profoundly decreased by ethanol exposure. This decrease was accompanied by increases in the frequencies of TUNEL- and caspase 3-positive cells and of cells exhibiting nuclear condensations. Thus, ethanol decreases the number of viable cells in vitro by slowing cell proliferation and increasing the incidence of cell death. The expression of the death indices in untreated cultures is most consistent with a single (apoptotic) pathway of cell death, rather than simultaneous apoptotic and necrotic modes of death. Furthermore, it appears that ethanol initiates an apoptotic death among cultured cortical neurons.     

A Cytochemical Technique for Demonstration of Lipids,Polysaccharides and Protein Bodies in Thick Resin Sections

An effective cytochemical technique for the simultaneous demonstration of lipids, polysaccharides and protein bodies in the same section from the tissue embedded in Epon 812 is described. Thick sections of peanut cotyledon are used for a typical sample according to the following procelures. Firstly, PAS reaction: (1) Oxidize sections in 0.5% periodic acid in 0.3% nitric acid for 10 min, (2) Wash in running water for 1–2 min and then pass through distilled water, (3) Stain in Schiff's reagent for 30 min, (4) Wash in sodium metabisulfite 3 times, 2 min for each time, (5) Wash in running water for 5 min and then pass through distilled water. Secondly, Sudan black B staining: (1) Rinse section in 70% ethanol for 1-2 min, (2) Stain in fresh 1% Sudan black B in 70% ethanol for 30–60 min at 40–60℃, (3)Rinse in 70% ethanol for 1 min and then in distilled water. Thirdly, Coomassie brilliant blue R staining: (1) Rinse sections in 7% acetic acid for 1–2 min, (2) Stain in I% Coomassie brilliant blue R in 7% acetic acid for 20 min at 60℃, (3) Differentiate in 0.1% acetic acid for I min, (4) Rinse in lunning water for 5 min and then pass through distilled water, (5) Dry at room temperature or in oven, 40℃. The dry sections mount in glycerin-gelatin. After the above three step staining, the three main compounds of the cell can be stained simultaneously. Starch grains and cellulose cell wall take cherry red colour, lipids appear in black, protein bodies are blue. The sealed slides can be kept permanently.     

New Uses for Calcium Chloride Solution as a Mounting Medium

Fresh cross sections of stems [Psilotum nudum, Coleus blumei, and Pelargonium peltatum] and roots (Setcreasea purpurea) 120 μm thick were fixed in FPA₅₀ (formalin: propionic acid: 50% ethanol, 5:5:90, v/v) for 24 hr and stored in 70% ethanol. The sections were transferred to water and then to 1% phloroglucin in 20% calcium chloride solution plus either hydrochloric, nitric, or lactic acid in the following ratios of phloroglucin-CaCl₂ solution:acid: 25:4, 20:2, or 15:5. The sections were mounted on slides either in one of the three mixtures or in fresh 20% calcium chloride solution. A rapid reaction of the acid-phloroglucin with lignin produced a deep red color in tracheary elements and an orange-red color in sclerenchyma. Fixed and stored leaf pieces from Nymphaea odorata were autoclaved in lactic acid, washed in two changes of 95% ethanol, transferred to water, and treated with the three acid-phloroglucin-calcium chloride mixtures. The abundant astrosclereids stained an orange-red color similar to that of sclerenchyma in the sections. In addition, a new method is reported for specifically staining lignified tissues. When sections or leaf pieces are stained in aqueous 0.05% toluidine blue O, then placed in 20% calcium chloride solution, all tissues destain except those with lignified or partially lignified cell walls. Thus, toluidine blue O applied as described becomes a reliable specific test for lignin comparable to the acid-phloroglucin test.     

Selective staining methods for cartilage of rat fetal specimens previously treated with alizarin red S.

A convenient method for staining cartilage with several basic stains after alizarin red S staining of bone was investigated in rat fetuses. It was found that bromophenol blue was useful and effective for staining of the margin and center areas of cartilage, even in specimens stored in glycerin for over 10 years. The specimens were washed in running tap water for 1 hr, and subsequently were immersed in water or in 70% ethanol at pH 4 for 1 hr or longer. The specimens were then stained with 0.005% bromophenol blue in 40% ethanol adjusted to pH 4 for 2 hr, or with 0.001% bromophenol blue in 40% ethanol adjusted to pH 4 for 24 hr. Furthermore, the bromophenol blue stain color actually faded when the specimens were immersed in water or in 70% ethanol at pH 8. Descending order of the stain-effective action on fetal rat cartilage for the basic stains tested was bromophenol blue, aniline blue, Evans blue, methyl violet, trypan blue, and water blue.     

Acid-sensitive channel inhibition prevents fetal alcohol spectrum disorders cerebellar Purkinje cell loss

Ethanol is now considered the most common human teratogen. Educational campaigns have not reduced the incidence of ethanol-mediated teratogenesis, leading to a growing interest in the development of therapeutic prevention or mitigation strategies. On the basis of the observation that maternal ethanol consumption reduces maternal and fetal pH, we hypothesized that a pH-sensitive pathway involving the TWIK-related acid-sensitive potassium channels (TASKs) is implicated in ethanol-induced injury to the fetal cerebellum, one of the most sensitive targets of prenatal ethanol exposure. Pregnant ewes were intravenously infused with ethanol (258+/-10 mg/dl peak blood ethanol concentration) or saline in a "3 days/wk binge" pattern throughout the third trimester. Quantitative stereological analysis demonstrated that ethanol resulted in a 45% reduction in the total number of fetal cerebellar Purkinje cells, the cell type most sensitive to developmental ethanol exposure. Extracellular pH manipulation to create the same degree and pattern of pH fall caused by ethanol (manipulations large enough to inhibit TASK 1 channels), resulted in a 24% decrease in Purkinje cell number. We determined immunohistochemically that TASK 1 channels are expressed in Purkinje cells and that the TASK 3 isoform is expressed in granule cells of the ovine fetal cerebellum. Pharmacological blockade of both TASK 1 and TASK 3 channels simultaneous with ethanol effectively prevented any reduction in fetal cerebellar Purkinje cell number. These results demonstrate for the first time functional significance of fetal cerebellar two-pore domain pH-sensitive channels and establishes them as a potential therapeutic target for prevention of ethanol teratogenesis.     

Toluidine Blue Staining of Coccidia in Cultured Animal Cells

Cultured animal cells infected with various species of Eimeria (coccidia) from chickens are washed in Hanks balanced salt solution (HBSS) and fixed in 5% formalin in HBSS. The fixed cultures are washed briefly in distilled water to remove HBSS salts and then dehydrated in a series of mixtures of 40 to 50% ethanol with increasing concentrations of tertiary butanol (TB) and decreasing concentrations of distilled water. Cultures are placed for 1 min in a mixture of 2 parts ethanol :TB (25:75) and 1 part 0.05% toluidine blue O in McIlvaine buffer (pH 6.0), followed by 1 min in 0.05% toluidine blue O in McIlvaine buffer (pH 6.0). The stained cultures are dipped for 1-2 sec in TB, allowed to dry and mounted permanently on slides. Cover-slip cultures fixed and stained by this procedure 8 years ago have not faded or discolored. The alcohol mixtures, formalin in HBSS, stain and buffer can be prepared in large volumes and stored indefinitely. The staining procedure has proven to be rapid and dependable with a variety of cell types in monolayer cultures in research and teaching applications.     

A Differential Stain for Rubber in Guayule

The following schedule, which combines an intense blue stain for rubber with sharply contrasting red counterstains, has been found satisfactory for use in an anatomical study of rubber deposition in guayule: Cut fresh or fixed sections about 50 to 100 % thick, transfer to 50% ethanol. Extract with acetone 5 minutes, treat with 1% NaOCl 5 minutes, saponify with 10% KOH in 95% ethanol 15 minutes, rinse 3 times with 50% ethanol, stain in oil blue NA (Calco) with safranin and Congo red 30 minutes at 55° C. Rinse in 50% ethanol 2 (or more) times to remove excess stain and mount in Karo syrup.     

Basic Blue 148: A Rapid Stain for T Helper Cells

After brief exposure to an aqueous solution of the oxazine textile dye C. I. basic blue 148 following fixation in 37% formalin, 95% ethanol and glacial acetic acid, T helper cell nuclei and cytoplasm in specimens of peripheral blood displayed a deep red-violet color. No other cell in normal blood or bone marrow specimens showed intense staining of this type. The total staining time is 1 min. Basic blue 148 stain is a promising technique for hematology and immunology laboratories as a rapid screening test for T helper cells in blood specimens using a microscopic slide and ordinary incandescent illumination.     

A Mixture of Methyl Green and Pyronin for Cell Fractionation Studies

A staining mixture consisting of 0.57% methyl green and 0.1 1 % pyronin B (calculated from the actual dye content) dis- solved in glycerol, 20 ml.; 2% aqueous phenol, 100 ml.; and 95% ethanol, 25 ml., was found to be optimum for differentiating cell components containing desoxypentose and pentose nucleic acids. The stain can be used for either fresh suspensions or unfixed dried smears of tissue homogenates. Nuclei are stained bright blue, and nucleoli and cytoplasmic particles, bright pink.     

Luxol Fast Blue Arn: A New Solvent Azo Dye with Improved Staining Qualities for Myelin and Phospholipids

Luxol fast blue ARN (Du Pont, C.I. solvent blue 37) is a diarylguanidine salt of a sulfonated azo dye. This dye was compared with other Luxol blue and Luxol black dyes. Luxol fast blue ARN has improved staining qualities for phospholipids and myelin, and can advantageously be substituted for Luxol fast blue MBS (MBSN). Appropriate staining times for a 0.1% dye solution in 95% ethanol (containing 0.02% acetic add) at 35°-40° C range from 2-3 hr. After staining, the sections should be rinsed in 95% ethanol, rinsed in distilled water, and differentiated for 2 sec in 0.005% Li₂CO₃, rinsed in 70% ethanol, washed in water, and counterstained as required. Phospholipids and myelin selectively stain deep blue. A fixative containing CaCl₂, 1%; cetyltrimethylammonium bromide, 0.5%; and formaldehyde, 10%, in water gave excellent results with brain. However, 10% formalin can be used. The staining of the phospholipids is probably due to the formation of dye-phospholipid complexes.     

Durable Staining of Cartilage in Foetal Rat Skeleton by Methylene Blue

Full term rat foetuses were skinned and eviscerated prior to fixation in 10% formol-saline. The bodies were then stained with 0.05% methylene blue in 17.5% aqueous ethanol. After preliminary immersion in 1% HC1 in 70% ethanol, differentiation was completed in 70% ethanol. Specimens were dehydrated in absolute ethanol, cleared in xylene and were preserved in a mixture of tri-N-butyl phosphate 17% and tricresyl phosphate 83%. Cartilage stained almost blue-black while other tissues were a very pale blue or were almost colourless.     

Differential staining of nerve cells and fibres for sections of paraffin-embedded material in mammalian central nervous system

A differential staining method is described of myelinated fibres and nerve cell bodies applicable to sections of mammalian, including human, central nervous system specimens embedded in paraffin wax. Experimental and human necropsy material fixed in acetic paraformaldehyde in phosphate buffer was used. Sections of 15–20 m in thickness were obtained, attached to slides, deparaffinized and hydrated. After hydration, sections are oxidized (30 s) in 2% potassium permanganate, bleached (1 min) in 5% oxalic acid and rinsed in distilled water. Staining is for 2–5 h in the following solution: 0.06% thionin, 1% formaldehyde, 10% acetic acid in distilled water. Sections are subsequently washed in distilled water, dehydrated through 96% and absolute ethanol, cleared in eucalyptol and mounted in Eukitt. Using the method described in the present paper, a differential coloration of myelin and neurons is obtained. Myelinated fibres appear red, whereas nerve cell bodies and glial nuclei are stained blue. This procedure provides a high contrast between myelin and cells suitable for observation and photography of sections. Simultaneous and differential coloration of both myelin and cells is easily and directly obtained with constant and homogeneous results.     

Investigation of gastroprotective compounds at subcellular level in isolated gastric mucosal cells

We tested the hypothesis that recognized gastroprotective agents exert direct protection against ethanol-induced injury in isolated rat gastric mucosal cells in vitro. If protection exists, we also wanted to identify subcellular targets in the reversible and/or irreversible stages of cell injury. Ethanol-induced cell injury was quantified by measuring plasma membrane leakage (trypan blue exclusion and lactate dehydrogenase release), mitochondrial integrity (succinic dehydrogenase), and nuclear damage (ethidium bromide-DNA fluorescence). Initial cell viability and responsiveness were estimated by the effects of carbachol, carbachol + atropine, or 16,16-dimethyl-PGE(2) on chief cell pepsinogen secretion. Enriched parietal cells were stimulated by histamine, carbachol, or histamine + IBMX. Preincubation of cells with PG, sucrose octasulfate, or the sulfhydryl compounds N-acetylcysteine, taurine, or cysteamine increased cell resistance 相似文献   

A polychromatic staining method for epoxy embedded tissue: a new combination of methylene blue and basic fuchsine for light microscopy

A simple and rapid method is described for staining semithin sections of material embedded in epoxy resin for observing tissues prior to transmission electron microscopy. The method is suitable for tissue fixed with a glutaraldehyde-formaldehyde mixture and postfixed in osmium tetroxide. No etching or oxidizing procedures are necessary. Sections 0.5-0.8 µm thick are dried onto a slide and stained with either 0.75% methylene blue and 0.25% azure B or 0.5% methylene blue and 0.5% azure II in 0.5% aqueous borax and heated over a flame for 8-10 sec. The slides are rinsed with water, then stained the same way with 0.1% basic fuchsine in 5% aqueous ethanol. Cytoplasm stains blue; nuclei darker blue; collagen, mucus and elastin pink to red; fat and intracellular lipid droplets gray-green.     

A polychromatic staining method for epoxy embedded tissue: a new combination of methylene blue and basic fuchsine for light microscopy

A simple and rapid method is described for staining semithin sections of material embedded in epoxy resin for observing tissues prior to transmission electron microscopy. The method is suitable for tissue fixed with a glutaraldehyde-formaldehyde mixture and postfixed in osmium tetroxide. No etching or oxidizing procedures are necessary. Sections 0.5–0.8 µm thick are dried onto a slide and stained with either 0.75% methylene blue and 0.25% azure B or 0.5% methylene blue and 0.5% azure II in 0.5% aqueous borax and heated over a flame for 8–10 sec. The slides are rinsed with water, then stained the same way with 0.1% basic fuchsine in 5% aqueous ethanol. Cytoplasm stains blue; nuclei darker blue; collagen, mucus and elastin pink to red; fat and intracellular lipid droplets gray-green.     

A polychromatic staining method for epoxy embedded tissue: a new combination of methylene blue and basic fuchsine for light microscopy.

A simple and rapid method is described for staining semithin sections of material embedded in epoxy resin for observing tissues prior to transmission electron microscopy. The method is suitable for tissue fixed with a glutaraldehyde-formaldehyde mixture and postfixed in osmium tetroxide. No etching or oxidizing procedures are necessary. Sections 0.5-0.8 microm thick are dried onto a slide and stained with either 0.75% methylene blue and 0.25% azure B or 0.5% methylene blue and 0.5% azure II in 0.5% aqueous borax and heated over a flame for 8-10 sec. The slides are rinsed with water, then stained the same way with 0.1% basic fuchsine in 5% aqueous ethanol. Cytoplasm stains blue; nuclei darker blue; collagen, mucus and elastin pink to red; fat and intracellular lipid droplets gray-green.