Survival of Airborne Pasteurella tularensis at Different Atmospheric Temperatures

The aerosol survival, recovery, and death rate of Pasteurella tularensis SCHU S5 disseminated in particle sizes of 1 to 5 mum were significantly affected by air temperature. The highest aerosol recovery of viable P. tularensis was observed within -7 and 3 C; the recovery decreased significantly below and above this temperature range. The death rate of airborne P. tularensis was not significantly influenced by an increase in temperature from -40 to 24 C. However, a progressive increase in atmospheric temperature from 24 to 35 C resulted in increased death rates; thus, a linear relationship appeared to be present between the temperature and death rates. At 49 C, the recoveries of viable airborne P. tularensis were significantly lower and the death rates were higher than at the other temperatures.     

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.     

Antibiotic control of tissue reactions in dogs vaccinated with viable cells of Coccidioides immitis

Castleberry, Merida W. (U.S. Army Biological Laboratories, Fort Detrick, Frederick, Md.), John L. Converse, and Peter J. Soto, Jr. Antibiotic control of tissue reactions in dogs vaccinated with viable cells of Coccidioides immitis. J. Bacteriol. 87:1216-1220. 1964.-A total of 12 dogs (15 to 25 lb each), vaccinated with viable Coccidioides immitis (subcutaneous injection of 260 viable arthrospores in the medial surface of the hind leg), resisted a respiratory challenge (aerosol) with the same organism (13,000 viable arthrospores) administered (aerosol) 2 months after vaccination. Oral amphotericin B therapy (150 mg of Fungizone per day for 21 days) of 6 of the 12 dogs, initiated immediately after vaccination, eliminated the undesirable side reactions of the viable vaccine (ulcerated vaccination site and inguinal lymphadenopathy exhibited by the 6 untreated dogs) without affecting the immunogenicity of the vaccine. Clinical observation (blood-urea nitrogen levels) during and after therapy and histological examination approximately 3 months after respiratory challenge failed to disclose any evidence of nephrotoxicity or renal damage due to the oral antibiotic therapy (total doses of more than 3 g of amphotericin B).     

Evidence that bacteria can form new cells in airborne particles.

Serratia marcescens incubated for 8 h at 31 degrees C in a chemically defined medium contained in shake flasks was aerosolized into rotating-drum aerosol chambers at 30 degrees C and saturated humidity. Cells furnished tryptone (Difco) and glycerol just before aerosolization increased (in viable numbers and countable cells) almost twofold within 1 to 2 h after becoming airborne, whereas cells not furnished additional tryptone decreased in viable numbers at a faster rate than the number of particles removed by gravitational settling. Limited tests with a Coulter Counter showed that cell volume changes occurred in growing cells that did not occur in the nongrowing population.     

Evidence that bacteria can form new cells in airborne particles.

Serratia marcescens incubated for 8 h at 31 degrees C in a chemically defined medium contained in shake flasks was aerosolized into rotating-drum aerosol chambers at 30 degrees C and saturated humidity. Cells furnished tryptone (Difco) and glycerol just before aerosolization increased (in viable numbers and countable cells) almost twofold within 1 to 2 h after becoming airborne, whereas cells not furnished additional tryptone decreased in viable numbers at a faster rate than the number of particles removed by gravitational settling. Limited tests with a Coulter Counter showed that cell volume changes occurred in growing cells that did not occur in the nongrowing population.     

Development of an Aerosol Model of Cryptococcus Reveals Humidity as an Important Factor Affecting the Viability of Cryptococcus during Aerosolization

Cryptococcus is an emerging global health threat that is annually responsible for over 1,000,000 infections and one third of all AIDS patient deaths. There is an ongoing outbreak of cryptococcosis in the western United States and Canada. Cryptococcosis is a disease resulting from the inhalation of the infectious propagules from the environment. The current and most frequently used animal infection models initiate infection via liquid suspension through intranasal instillation or intravenous injection. These models do not replicate the typically dry nature of aerosol exposure and may hinder our ability to decipher the initial events that lead to clearance or the establishment of infection. We have established a standardized aerosol model of murine infection for the human fungal pathogen Cryptococcus. Aerosolized cells were generated utilizing a Collison nebulizer in a whole-body Madison Chamber at different humidity conditions. The aerosols inside the chamber were sampled using a BioSampler to determine viable aerosol concentration and spray factor (ratio of viable aerosol concentration to total inoculum concentration). We have effectively delivered yeast and yeast-spore mixtures to the lungs of mice and observed the establishment of disease. We observed that growth conditions prior to exposure and humidity within the Madison Chamber during exposure can alter Cryptococcus survival and dose retained in mice.     

Low translocation of Bacillus thuringiensis israelensis to inner organs in mice after pulmonary exposure to commercial biopesticide

Translocation of viable cells from a Bacillus thuringiensis israelensis-based biopesticide to inner organs in a mouse model was studied. Mice were exposed to the originally formulated product through the lungs and gastrointestinal tract by intratracheal instillation. Colony forming units (CFU) were grown from lungs, caecum, spleen and liver on Bacillus cereus-specific agar (BCSA) after 24 h and finally determined to be biopesticide strain B. t. israelensis by large plasmid profile. No CFU were found in spleen or liver of the control mice or in any aerosol background or material. We have shown that viable cells from the commercial product can translocate to spleen and liver of immunocompetent mice in a dose-dependent manner. Furthermore, we discuss the methods of exposure and how bacterial translocation should be taken into consideration when evaluating the safety of novel or reintroduced biopesticides in the future.     

Growth and death behaviour of anchorage-independent animal cells immobilized within porous support matrices

Summary Growth and death of anchorage-independent animal cells entrapped within porous biomass support particles (BSPs) in static or shake-flask cultures were evaluated by comparison of enzyme activity with non-immobilized cells grown under static culture using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay and release of lactate dehydrogenase into the culture medium. Mouse myeloma MPC-11 (ATCC CCL 167) cells inoculated within porous polyvinyl formal resin BSPs (3 × 3 × 3 or 2 × 2 × 2 mm; mean pore diameter, 60 ) grew exponentially at a specific growth rate comparable to that of non-immobilized cells in the initial period of incubation. Entrapped cells then reached the stationary phase with a cell density over 10⁷ cells/cm³ BSP. The death rate of entrapped cells increased in response to the rise in viable cell density in the BSPs. Observation of viable cell distribution within the BSPs using MTT staining indicated that the cells concentrated within a thin outer shell of the BSPs with time. After the immobilized cells reached the stationary phase, penetration of cells into the outer shell ceased and heterogeneous distribution of cell density occurred in the viable cell layer in the shake-flask culture.     

Isolation of alveolar epithelial cells from lung tissue obtained at autopsy

Summary Lung alveolar epithelial cells have been studied in a variety of laboratory animal models, and studies of human alveolar epithelial cells are important for comparison to information obtained from animal studies. Autopsy material is a source of human cells for study. Studies of human autopsy material revealed variables that negatively affected the yield of viable cells. For specimens from adults, these included death greater than 12 h before cell isolation, obvious severe lung fibrosis, longstanding metabolic disorders, and lung congestion indicated by weight of the right middle lobe greater than 150 g. Samples from children yielded significant numbers of viable cells up to 18 h after death. For 17 specimens that conformed to the above criteria, approximately 8.5×10⁶ alveolar cells were obtained per gram of tissue (tissue weights ranged from 30 to 108 g) using a procedure involving instillation of proteases into the airways. The cells could be further fractionated, and 10 to 15% of the mixed cells obtained were type II pneumocytes. Analysis of NADPH cytochrome-c-reductase distribution in subcellar fractions provided evidence that the cells obtained were intact. Phospholipid enzyme activities and synthetic activity were within the ranges previously found in laboratory studies of freshly obtained animal lungs. These results suggest that significant numbers of viable and functional human lung cells, including type II pneumocytes, can be obtained from autopsy material. This research was supported by a grant (HL 33083) from the National Heart, Lung and Blood Institute, Bethesda, MD.     

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.     

Novel rapid method for visualization of extent and location of aerosol contamination during high-speed sorting of potentially biohazardous samples

BACKGROUND: Containment of potentially biohazardous aerosols that result from high-speed sorting of human cells has been an increasingly important problem in analytical cytometry. The current method for assessing the efficiency of aerosol containment involves detection of aerosols containing sorted T4 bacteriophage on lawns of T4-susceptible Escherichia coli on plates that are placed in and around the sort area. Although this method is sensitive, it is time consuming and involves maintenance and handling of bacteria and sorting of bacteriophage that may themselves serve as sources of contamination for sorted viable human cells. METHODS: Glo Germ (5-microm melamine copolymer resin beads), which are fluorescent under black light illumination, were sorted on a Beckman-Coulter Elite ESP sorter in order to visualize deposition of aerosols under normal and mock failure modes. RESULTS: Glo Germ was successfully used under both normal sorting conditions, as well as mock failure mode, to visualize aerosol formation. CONCLUSIONS: We have developed a method to examine aerosol containment using modified Glo Germ, a product used for teaching aseptic technique in hospitals, industry, restaurants, and schools. Use of this technique represents a rapid, inexpensive, qualitative analysis of the extent and location of aerosol contamination from cell sorters.     

Testing and evaluation of off-gas filters for bioreactors by a new bacterial aerosol challenge test method (TBAC).

A TNO bacterial aerosol challenge (TBAC) filter test rig was developed for direct assessment of the effectiveness of bioreactor off-gas filters as an alternative to routinely applied indirect wet integrity testing (IT). This TBAC test rig is based on bacterial aerosol challenging with Pseudomonas diminuta and dual monitoring by laser particle counting (LPC) and Andersen microbial sampling (AMS) of viable cells. The TBAC filter test rig is able to reproduce the various conditions encountered in fermentation processes. In experiments with several filters from one class, it was demonstrated that some filters were actually penetrated by up to 3,000 viable cells per test, despite their approval by commercially available IT test equipment. Repetitive filter use, prolonged use, and autoclaving of filters resulted in an increase in pressure drop over the filter but improved the performance of leaking/deviant filters due to building up of a filter cake (this phenomenon was identified by electron microscopy). The integrity tests used were found inadequate for accurate assessment of filter quality. Certification of filter lots by random tests of commercially available off-gas filters using sensitive direct methods such as those presented here might be advisable, as not all filters purchased were of appropriate quality.     

Feasibility of using real-time optical methods for detecting the presence of viable bacteria aerosols at low concentrations in clean room environments

An experimental investigation was carried out to determine the agreement between two methods of viable bacteria aerosol detection. Various amounts of Bacillus globigii (BG) spores were aerosolized in 1-s bursts into a HEPA-filtered air stream and sampled simultaneously with a fluorescence aerosol particle sensor (FLAPS) and a slit to agar biological air sampler. The slit sampler incorporated 150-mm malt extract culture plates, which were incubated at 37°C for at least 12 h before culturable BG particles were counted in terms of colony-forming units (CFU). A relationship between CFU and optically detected viable bacteria particles was determined as culturable particle concentrations decreased. Through further analytical procedures, the FLAPS showed a limit of detection (LOD) of 4.2 bacterial particle/2.5 l of sampled air or 1.7 × 10³ m⁻³. This real-time bacteria aerosol monitor could be used to detect burst contamination events during a surgical procedure. The technology may be used for developing a dose–response relationship between bacterial particle exposure and infection, a tool potentially helpful in determining patient risk.     

Kinetic model for nitrogen-limited wine fermentations.

A physical and mathematical model for wine fermentation kinetics has been developed to predict sugar utilization curves based on experimental data from wine fermentations with various initial nitrogen and sugar concentrations in the juice. The model is based on: (1) yeast cell growth limited by nitrogen; (2) sugar utilization rates and ethanol production rates proportional solely to the number of viable cells; and (3) a death rate for cells proportional to alcohol content. All but one parameter in the model can be estimated from existing data. However, experiments to find this final parameter, a constant describing cell death, indicate that cell death may not be the critical factor in determining fermentation kinetics as cell viability remains significant until sugar utilization has ceased. The model, nevertheless, predicts a transition from normal to sluggish to stuck fermentations as initial nitrogen levels decrease. It also predicts that fermentations with high initial Brix levels may go to completion when supplemented with nitrogen in the form of ammonia. Therefore, we hypothesize that the model is valid but that ethanol causes the yeast cells to become inactive while remaining viable. Experimental verification of the model has been performed using flask-scale experiments. The model has also been used to evaluate the possibility of using nitrogen or viable cell additions to avoid or correct problem (i.e., sluggish or stuck) fermentations.     

Determination of cell lysis and death kinetics in continuous hybridoma cultures from the measurement of lactate dehydrogenase release

The death of the hybridoma VO 208 in a continuous culture at pH 7 and 6.8 was investigated by measuring both the appearance of visible dead cells which do not exclude the trypan blue dye and the release of lactate dehydrogenase (LDH) in the culture medium. The intracellular LDH was found to be completely released either when live cells lysed or when they were transformed into visible dead cells. No significant lysis of blue dead cells could be observed at the two different pH. Using a LDH balance over the culture system, cell lysis was found negligible at pH 7, but accounted for 20% of the total cell death at pH 6.8. A methodology is proposed to evaluate the rate constants of hybridoma lysis and total death. For the investigated cell line in continuous culture, the calculated total cell death rate constant was found to increase from 0.002 h^–1 to 0.01 h^–1 when decreasing the pH from 7 to 6.8.Abbreviations D dilution rate (h^–1) - k_b specific trypan-blue dead cells appearance rate (h^–1) - k_L specific lysis rate of viable cells (h^–1) - k_d specific death rate (h-1) - LDH₀ lactate dehydrogenase activity in the feed culture medium (IU.l^–1) - LDH lactate dehydrogenase activity in the outlet culture medium (IU.l^–1) - LDH_i intracellular lactate dehydrogenase activity of viable cells (IU.10^–9 cells) - r_LDH total rate of LDH release (IU.h^–1.L^–1) - r_b transformation rate of viable cells into blue dead cells (10⁹ cells.h^–1.L^–1) - x_v viable cell concentration (10⁹ cells.l^–1) - x_b trypan-blue dead cell concentration (10⁹ cells.l^–1)     

Caspase-3在roscovitine诱发PC12细胞凋亡中发挥重要作用

我们已证实周期蛋白激酶（cyclin-dependent kinases）cdk2、cdc2和cdk5抑制剂roscovitine诱导PC12细胞凋亡。本实验应用caspase-3免疫细胞化学与hoechst 33342荧光化学双标、MTT比色法细胞活性测定和Western blot方法,研究了caspase-3在roscovitine所致PC12细胞凋亡中的作用。结果显示,roscovitine（50μmol／L）处理PC12细胞12h,细胞核染色质凝缩及核碎片形成,同时胞浆中出现caspase-3阳性标志,caspase-3阳性细胞占细胞总数的42％。非特异性caspases抑制剂Z-VAD-FMK（50μmol／L）和caspase-3特异性抑制剂Z-DEVD-FMK（100μmol／L）可部分降低roscovitine所致的细胞死亡,使细胞存活率分别由29．03％（roscovitine）增至58．06％（Z-VAD-FMK＋roscovitine）和45．16％（Z-DEVD-FMK＋roscovitine）：用单克隆non-erythroid α-spectrin抗体检测roscovitine处理组细胞匀浆提取液,表明caspase-3裂解的特异性spectfin 120kDa蛋白产物较对照组显著增加。提示细胞凋亡成分caspases参与roscovitine所敛的细胞凋亡,其中caspase-3发挥重要作用。     

Removal of Viable Airborne Fungi from Indoor Environments by Benzalkonium Chloride-Based Aerosol Disinfectants

Fungi are ubiquitous in indoor environments, and some taxa can cause clinical symptoms in humans. Thus, from the viewpoint of public health, methods to reduce indoor airborne fungi are needed. The goal of this study was to examine the efficacies of benzalkonium chloride (BAC)–based aerosol disinfectants to remove airborne viable fungi from indoor environments. The laboratory- and field-based experiments were conducted to compare airborne culturable fungal concentrations before and after the disinfectant aerosol applications. The laboratory-based experiments showed the greater efficacies by the BAC-based disinfectant aerosol than by pure-water control aerosol (p <.05, t-test). In the field study using the BAC-based disinfectant aerosols, on average a 58% reduction of total airborne culturable fungal concentrations were observed. Additionally, the significant reduction was found for a group of airborne yeasts or yeast-like organisms (p <.05, Wilcoxon signed rank test). The BAC-based aerosol disinfectants are effective when used to reduce the numbers of airborne culturable fungi, in particular yeasts or yeast-like organisms, from indoor environments.     

Dynamics of artificially immobilized Nitrosomonas europaea: Effect of biomass decay

The dynamics of growth and death of immobilized Nitrosomonas europaea were studied. For this, the death rate of suspended cells was determined in the absence of ammonium or oxygen by following the loss of respiration activity and by fluorescein-diacetate (FDA)/lissamine-green staining techniques. The death rates obtained (1.06 x 10(-6) s(-1) or 4.97 x 10(-6) s(-1) in the absence of oxygen or ammonium, respectively) were incorporated in a dynamic growth model and the effects on the performance of the immobilized-cell process illustrated by model simulations.These model simulations and experimental validation show that if decay of biomass occurs the biomass concentration in the center of the bead decreases. As a result, the systems react slower to changes in substrate concentrations than if all cells remain viable.To show that cells in the center of the bead died, the FDA and lissamine-green staining techniques were adapted for immobilized cells. It was shown that biomass decay occurred, especially in the center of the bead; the amount of cells decreased there, and the remaining cells were all stained with lissamine green indicating cell death. After the substrate availability was decreased, also cells near the surface of the bead lost their viability. The number of viable cells increased again after increasing the substrate concentration as the result of cell multiplication. At low substrate concentrations and low hydraulic retention times, as for example in the treatment of domestic wastewater, the death rate of cells is thus an important parameter for the performance of the immobilized-cell system. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 55: 630-641, 1997.     

Assessment of cell viability by flow cytometric analysis using DNase exclusion

A new method was developed for selective measurement of DNA distributions in viable cell populations. The method is based on the fact that non-viable cells lose membrane integrity and treatment of such cells with DNase should remove their DNA. The DNase-treated cells were stained with DNA fluorochrome 4′-6-diamidino-2-phenylindole (DAPI) in the presence of Triton X-100. DNA distribution was measured by flow cytometry prior to and after treatment with DNase. Percentage of cells stained after DNase treatment was considered as an index of cell viability. Optimal conditions for DNase treatment and application of DNase exclusion test for the analysis of spontaneous cell death, selective death of cells arrested in S/G2 phases, instant cell disintegration induced by cytotoxic compounds and cell death induced by hyperthermia are described.