Microbiological Aspects of Ethylene Oxide Sterilization: II. Microbial Resistance to Ethylene Oxide

The death rate kinetics of several sporeforming and nonsporeforming microorganisms, including radiation-resistant cocci, were determined by exposing them to a mixture of ethylene oxide and dichlorodifluoromethane (500 mg of ethylene oxide per liter, 30 to 50% relative humidity, and 54.4 C). Spore survivor curves obtained from tests of inoculated and exposed hygroscopic and nonhygroscopic carriers showed that the spores of Bacillus subtilis var. niger are more resistant to ethylene oxide than are spores of Clostridium sporogenes, B. stearothermophilus, and B. pumilus. The decimal reduction times (expressed as D values at 54.4 C-500 mg of ethylene oxide per liter) obtained under the test conditions for B. subtilis var. niger spores on hygroscopic and nonhygroscopic carriers exceeded the values obtained for the other organisms considered, both sporeformers and nonsporeformers. The decimal reduction times for the vegetative cells of the radiation-resistant organisms (Micrococcus radiodurans and two strains of Streptococcus faecalis) and the ATCC strain of S. faecalis demonstrated comparable resistance to ethylene oxide with the spores of C. sporogenes, B. stearothermophilus, and B. pumilus, but not those of B. subtilis var. niger.     

Resistance of Micro-organisms to Inactivation by Gaseous Ethylene Oxide

A simple method for the exposure of micro-organisms to ethylene oxide on membrane filters in a modified desiccator has been devised and used to study microbial resistance to the gaseous sterilant and the term ' R -value' is suggested to express this. The resistance of many known species and isolates has been assessed and compared. Several species of Bacillus were isolated from natural habitats and their spores were found to be more resistant than the strain of Bacillus subtilis var. niger (NCTC 10073) frequently used to monitor ethylene oxide sterilization. However, endospores of some bacterial species exhibited little resistance. Fungal spores and vegetative bacteria exhibited low resistance to the sterilant except after drying in organic material when they appeared more resistant than spores of B. subtilis var. niger. It was concluded that resistance to ethylene oxide did not correlate with resistance to heat, irradiation or other chemical disinfectants, or to the existence in the endospore form per se.     

Ethylene Oxide Gaseous Sterilization: II. Influence of Method of Humidification

The duration of the equilibration period between admission of water vapor and subsequent introduction of gaseous ethylene oxide to an evacuated sterilizer chamber was studied with respect to its effect on the inactivation of spores of Bacillus subtilis var. niger under simulated practical conditions. Introduction of a water-adsorbing cotton barrier between the spores and an incoming gas mixture of water vapor and ethylene oxide caused a marked increase in the observed thermochemical death time of the spore populations. This effect was negated by admission of water vapor one or more minutes prior to introduction of ethylene oxide gas. Increases in temperature and relative humidity of the system promoted passage of water vapor through the cotton barriers and diminished their effect.     

The effect of storage and active ingredient properties on the drug release profile of poly(ethylene oxide) matrix tablets

Different molecular weight forms of poly(ethylene oxide) can be used successfully in controlled release drug delivery due to their excellent matrix forming properties. Drug release of these materials follows nearly zero order kinetics, and is mainly governed by polymer swelling and erosion and diffusion of drug molecules. Because of its partly amorphous structure, poly(ethylene oxide) undergoes structural changes caused by elevated temperature and relative humidity of the storage medium resulting in an increased drug release. This physical process can be highly influenced by the structure of different drug molecules, such as polymer-binding ability and hydration tendency. These properties of two basic drugs embedded into poly(ethylene oxide) matrices were characterized by molecular modelling and an attempt was made to reveal their effect on the change of drug release stability, a prerequisite of the marketing authorization of dosage forms. The findings suggest that both the hydration properties of the active ingredient and the molecular weight of the polymer influence the effect of physical ageing of poly(ethylene oxide) on the drug release properties of the matrix.     

Ethylene Oxide Gaseous Sterilization: I. Concentration and Temperature Effects

The relationships of reaction temperature and concentration of gaseous ethylene oxide to the time required for inactivation of air-dried Bacillus subtilis var. niger spores are more complex than previously reported. A plot of temperature vs. the logarithm of “thermochemical death time” (TCDT) resulted in a straight line between 18 and 57 C for systems of “high” ethylene oxide concentration. The TCDT values were independent of ethylene oxide concentrations above certain temperature-dependent limits. A given ethylene oxide concentration produced a TCDT curve identical in the upper temperature regions with that for higher concentrations. As the temperature was lowered beyond a critical point, this curve diverged from that for higher concentrations, as a straight line of lesser slope. Thus, a series of curves exists for a range of ethylene oxide concentrations. They are characterized by two segments, both logarithmic, intersecting at a critical temperature for each concentration. The intersecting point is at a temperature inversely related to the ethylene oxide gas concentration. The temperature quotient for the high temperature segments of all systems was 1.8. This value was characteristic for ethylene oxide concentrations of 440 and 880 mg/liter at temperatures above 40.6 and 33.4 C, respectively. Below these critical temperatures, the Q₁₀ values for the respective systems were 3.2 and 2.3.     

Microbiological Aspects of Ethylene Oxide Sterilization: III. Effects of Humidity and Water Activity on the Sporicidal Activity of Ethylene Oxide

An investigation determined the effects of environmental moisture content or water activity (Aw), exposure humidity, and sterilant concentration on the resistance of microbial spores. Decimal reduction values [expressed as D values at 54.4 C-specified concentration (milligrams per liter) of ethylene oxide] were determined from spore destruction curves of Bacillus subtilis var. niger dried on hygroscopic and nonhygroscopic surfaces. Four groups of spore preparations were preconditioned in one of four Aw environments (<0.1, 0.1, 0.5, 0.95) for 2 weeks or longer and were exposed to 500 mg of ethylene oxide per liter at 54.4 +/- 3 C and 10, 50, and 95% relative humidity in a specially designed thermochemical death rate apparatus. A fifth group did not receive any preconditioning treatment and was exposed immediately after preparation, in the same apparatus at the same temperature, to ethylene oxide concentrations of 200, 400, 600, 800, and 1,200 mg/liter and relative humidities of 15, 30, 50, 60, and 90%. The resistance of the spores on both types of surfaces to ethylene oxide increased proportionately with the Aw of the conditioning environment. The study also showed that moisture in the exposure system was not as critical a variable as the ethylene oxide concentration. The spore destruction rates, irrespective of the carrier types at all concentrations and at different humidities, varied little from one another. The decimal reduction values were reduced as the ethylene oxide concentration increased, and no optimal exposure humidity concentration was observed.     

Portable Ethylene Oxide Sterilization Chamber

A portable ethylene oxide sterilization chamber was designed, constructed, and tested for use in the sterilization of embolectomy catheters. The unit can accommodate catheters up to 40 inches (101.6 cm) in length and can be operated for less than 4 cents per cycle. A constant concentration of 500 mg of ethylene oxide per liter of space and holding periods of 4 and 6 hr at 43 and 22 C, respectively, were adequate when tested with B. subtilis spores. The estimated cost of construction was $165.00. If temperature control is unnecessary, the cost is approximately $80.00.     

Microbiological Aspects of Ethylene Oxide Sterilization: I. Experimental Apparatus and Methods

A specially built thermochemical death-rate apparatus is described which can be used to determine the resistance of microorganisms to ethylene oxide under controlled conditions. The apparatus was designed to provide instantaneous exposure of microorganisms to ethylene oxide and to eliminate variables that could result in errors when death kinetic reaction rates are calculated. The apparatus is used to obtain ethylene oxide resistance data which are useful in evaluating and developing sterilizing cycles for materials with known bacterial concentrations, as well as for calculating probability factors on which a given test condition can be expected to provide sterilization.     

Effect of Moisture on Ethylene Oxide Sterilization

Bacterial cells dehydrated beyond a critical point no longer react uniformly to ethylene oxide sterilization. The percentage of cells resistant to the lethal effect of ethylene oxide after desiccation is often as small as 0.1 to 0.001%. However, 5% resistant cells were observed with one type of microorganism dried in broth. The presence of organic matter increases the percentage of cells that become resistant to ethylene oxide after dehydration. The phenomenon is produced by exposing cells to a vacuum or a chemically desiccated atmosphere. It is not a permanent change, because the resistant cells rapidly become susceptible if wetted with water. On the other hand, mere exposure to a high relative humidity (RH), i.e., 75 to 98%, after desiccation requires 6 and 4 days, respectively, to overcome this resistance. Moisture studies showed that there is less water in bacterial cells that have been desiccated and then equilibrated to successively high RH values up to 100% RH, than in cells that have not been desiccated, but allowed to dry naturally until equilibrated to the same RH values.     

一氧化氮在乙烯诱导蚕豆气孔关闭中的作用

以蚕豆为材料研究了一氧化氮(nitric oxide,NO)和乙烯对气孔运动的影响。结果表明,10μmol/L的NO供体硝普钠(sodium nitroprusside,SNP)以及0.04%的乙烯能明显诱导蚕豆气孔关闭,并且二者共同处理后,能够增强其促进气孔关闭的作用。乙烯合成抑制剂AVG可以减弱NO诱导气孔关闭的程度,NO清除剂c-PTIO和NR抑制剂NaN3也可减弱乙烯诱导气孔关闭的程度,而一氧化氮合酶(nitric oxide synthase,NOS)抑制剂L-NAME对乙烯诱导气孔关闭的作用不明显。推测,在调控蚕豆气孔关闭过程中,NO可能主要通过NR途径参与乙烯调控气孔关闭过程。     

Effects of Ethylene Oxide on the Tissue and Flora of Fresh and Freeze Dried Cod Fillets

S ummary . Attempts to sterilize fresh cod fillets with ethylene oxide resulted in protein denaturation with the commensurate exudation of soluble tissue materials. The bacterial colony forming units were reduced to a level of between zero and 100/g of tissue, but sterilization was never achieved. Freeze dried cod fillet sections treated with ethylene oxide and reconstituted with sterile Ringer's solution gave a sterile product which when inoculated with a natural bacterial flora produced normal spoilage odours.     

外源NO对瓶插期间的月季切花中内源激素含量的影响

以硝普钠（SNP）为一氧化氮供体,研究NO及其清除剂2-苯基-4,4,5,5-四甲基咪唑啉-1-羟-3-氧（PTIO）影响月季瓶插期间的生理指标和内源激素含量的结果表明：0.1mmol.L-1SNP释放的NO抑制月季切花瓶插期间花瓣中内源乙烯释放速率和ABA含量的升高,延缓IAA含量的下降,并保持组织中相对较低的ZR和GA水平。PTIO则可促进花瓣中的乙烯、ABA、ZR和GA含量的升高和IAA含量的下降。     

Ethylene Oxide Resistance of Nondesiccated and Desiccated Spores of Bacillus subtilis var. niger Hermetically Sealed in Various Polymeric Films

The resistance to destruction of spores of Bacillus subtilis var. niger hermetically sealed in various polymeric films and exposed to ethylene oxide with and without relative humidity was determined. The effect of desiccation was also determined. The order of increased resistance to sterilization with regard to type of polymeric film was found to be: polyethylene equal to polyvinyl chloride, less than nylon, less than cellophane/polyethylene laminate, less than phenoxy, less than mylar/polyethylene laminate. Desiccated spores sealed in various polymeric films were much more resistant to ethylene oxide sterilization than nondesiccated spores. Relative humidity was an important factor in ethylene oxide sterilization with spores not sealed in polymeric films. However, with spores hermetically sealed in polyethylene, added relative humidity was an insignificant factor in the sterilization process.     

Microbiological Aspects of Ethylene Oxide Sterilization: IV. Influence of Thickness of Polyethylene Film on the Sporicidal Activity of Ethylene Oxide

Spores of Bacillus subtilis var. niger, dried on nonhygroscopic and hygroscopic surfaces, were enclosed in one of four thicknesses of low-density polyethylene film (2, 4, 6, and 20 mils). The surfaces were then placed in a specially designed thermochemical death rate apparatus and exposed to an ethylene oxide concentration of 600 mg/liter (at 54.4 C) and 50% relative humidity. Survival data, including both spore survivor curves and decimal reduction values (expressed as D values at 54.4 C-600 mg of ethylene oxide per liter), demonstrated similar survivor patterns when the B. subtilis var. niger spores were enclosed in low-density polyethylene films 2, 4, and 6 mils thick. A comparison of these patterns with those of spores enclosed in glassine and subjected to identical exposure conditions revealed only slight variations. The use of 20-mil polyethylene film greatly increased the time required to kill B. subtilis var. niger spores under the exposure conditions.     

Comparison of Two Methods for Enumeration of Anaerobe Numbers on Forages and Evaluation of Ethylene Oxide Treatment for Forage Sterilization

Experiments were conducted to (i) compare most-probable-number (MPN) procedures with roll tube procedures for enumeration of forage anaerobic bacteria and (ii) evaluate the efficacy of using ethylene oxide to sterilize wet herbage. Alfalfa, corn, and alfalfa-orchardgrass silages and alfalfa and orchardgrass herbages were analyzed for total anaerobic bacteria (medium pH, 6.8) and acid-tolerant anaerobic bacteria (medium pH, 4.5) by both roll tube and MPN procedures. No difference was found between the roll tube and MPN procedures for total bacteria; however, higher counts were obtained for acid-tolerant bacteria when the MPN procedure was used. Although MPN procedures require less time to obtain an estimate of bacterial numbers, isolation and identification of the microbial population is not possible. Alfalfa herbage was treated with ethylene oxide for 12, 24, or 36 h, incubated for 7 days at 37°C with or without addition of a bacterial inoculant, and analyzed for total bacteria by MPN procedures. Microbial growth after inoculation of ethylene oxide-treated herbage indicated that there was insufficient residual ethylene oxide to inhibit subsequent microbial growth. The results also indicated that 24 h was required to adequately sterilize fresh herbage. Thus, ethylene oxide can be used to sterilize wet herbage for use as a substrate for pure cultures of silage bacteria.     

一氧化氮与植物成熟衰老的关系

植物体可以通过依赖于类似哺乳动物的一氧化氮合成酶或硝酸还原酶的酶促合成途径和非酶促合成途径产生一氧化氮。植物内源一氧化氮可以通过抑制乙烯的生物合成和调控环化核苷酸在植物组织中的水平,来延缓植物组织的成熟和衰老,延长果蔬等组织的货架期。     

Limitations of Thioglycolate Broth as a Sterility Test Medium for Materials Exposed to Gaseous Ethylene Oxide

Although ethylene oxide is a reliable sterilizer, the process may be limited by diffusion. Thus, situations may exist where microorganisms are protected from the sterilizing gas. It is possible that the exterior of a substance may be sterilized, whereas the interior is not. We investigated three general types of materials in which this limitation of diffusion could occur: the bore of glass and plastic tubing, the center of cotton balls, and plastic adhesive film/paper backing interface. These materials were contaminated as close to their geometric center as possible with Bacillus subtilis var. niger spores occluded in crystals of sodium chloride. After exposure of the contaminated materials (except aluminum foil) to ethylene oxide, thioglycolate broth (a standard sterility-test medium) indicated sterility, whereas Trypticase Soy Broth indicated nonsterility. It is likewise possible that aerobic microorganisms, surviving in or on material after exposure to dry heat or steam sterilization processes, would not be recovered by thioglycollate broth. Entrapped aerobic organisms will probably not grow out in the low oxygen tension zone of an anaerobic medium such as thioglycollate broth. It is recommended than an aerobic medium such as Trypticase Soy Broth be used concurrently with thioglycolate broth for sterility testing.     

Nitric Oxide Regulates Dark-Induced Leaf Senescence Through EIN2 in Arabidopsis

The nitric oxide (NO)-deficient mutant nos1/noa1 exhibited an early leaf senescence phenotype. ETHY-LENE INSENSITIVE 2 (EIN2) was previously reported to function as a positive regulator of ethylene-induced senescence. The aim of this study was to address the question of how NO interacts with ethylene to regulate leaf senescence by characterizing the double mutant ein2-1 nos1/noa1 (Arabidopsis thaliana). Double mutant analysis revealed that the nos1/noa1-mediated, dark-induced early senescence phenotype was suppressed by mutations in EIN2, suggesting that EIN2 is involved in nitric oxide signaling in the regulation of leaf senescence. The results showed that chlorophyll degradation in the double mutant leaves was significantly delayed. In addition, nos1/noa1-mediated impairment in photochemical efficiency and integrity of thylakoid membranes was reverted by EIN2 mutations. The rapid upregulation of the known senescence marker genes in the nos1/noa1 mutant was severely inhibited in the double mutant during leaf senescence. Interestingly, the response of dark-grown nos1/noa1 mutant seedlings to ethylene was similar to that of wild type seedlings. Taken together, our findings suggest that EIN2 is involved in the regulation of early leaf senescence caused by NO deficiency, but NO deficiency caused by NOS1/NOA1 mutations does not affect ethylene signaling.     

生长素、乙烯和一氧化氮对拟南芥下胚轴插条形成不定根的调节

研究生长素、乙烯和一氧化氮（NO）对拟南芥下胚轴插条形成不定根的调节,以及生长素和乙烯信号转导成员在IAA促进不定根形成中的作用的结果表明：拟南芥切条以IAA和硝普钠（N0供体）单独处理7d后的不定根形成均受到促进,其中以50μmol·L^-1 IAAμmol·L^-1 SNP的促进作用为最强,乙烯的促进作用不明显;生长素运输和信号转导以及乙烯信号转导相关突变体对IAA促进生根作用的敏感性比野生型有所下降,特别是IAA14功能获得型的突变体。IAA和NO在促进不定根形成中有协同效应。     

A Bacterial Spore Test Piece for the Control of Ethylene Oxide Sterilization

Aluminium foil strips carrying varying numbers of spores of the Camp Detrick strain of Bacillus subtilis dried from water, 90% (v/v) methanol, 5 and 20% (v/v) serum, nutrient broth and isotonic saline were examined for their possible use as test pieces for the control of sterilization by ethylene oxide. Methanolic suspensions of these spores were found to be stable on storage, and foils carrying spores dried from methanol were the most reproducible and stable of those tested. The susceptibility of the test piece system could be controlled by varying the numbers of spores on each foil and the numbers of foils used per test.