Effects of oxygen,carbon dioxide,and nitrogen on hatching behavior and hatching time in the katydid,Eobiana engelhardti subtropica Bey-Bienko (Orthoptera: Tettigoniidae)

The trigger for the hatching behavior and determination of hatching time of the katydids, Eobiana engelhardti subtropica (Orthoptera: Tettigoniidae) have been shown to be influenced by light–dark signals or temperature. In this study, I investigated the effects of oxygen, carbon dioxide, and nitrogen on the hatching behavior and hatching time of the katydid. Eggs rarely hatched under a constant temperature of 25°C and hatched sporadically at a constant temperature of 15°C under continuous light in the air. However, when eggs were exposed to 100% oxygen or a mixture of oxygen and nitrogen (2:1 or 1:1), hatching occurred within a few seconds. Hatching behavior was directly triggered by high concentrations of oxygen. It was inhibited by exposure to 100% carbon dioxide, 100% nitrogen, or a mixture of oxygen and nitrogen (1:2). The hatching time, determined by the temperature fall (transfer from 25°C to 15°C), was delayed by these gases, and was reset by the transfer back of eggs to the air. This suggests the existence of a time-measuring mechanism that is triggered by the transfer of eggs to the air. These results, indicating that hatching behavior was directly triggered by high concentrations of oxygen and that hatching time was set by the transfer from carbon dioxide or nitrogen to the air, are new findings to the best of my knowledge.     

Membrane energization at subzero temperatures: calcium uptake and oxonol-V responses

The use of aprotic solvents for preserving the electron transport properties of mitochondria at subzero temperatures is based upon the use of binary water and ethylene glycol mixtures or upon ternary and quaternary mixtures that include dimethyl sulfoxide and the lower aliphatic alcohols. In order to better preserve the respiratory control properties of mitochondria at subzero temperatures, detailed studies have been made of the effects of these mixtures on the respiratory control and electron transport from NADH or succinate of mitochondrial preparations. It is found that ADP is not metabolized at a measurable rate below 0 °C, but that Ca²⁺ is rapidly taken up and can thus be used to assay respiratory control ratios down to ?8 °C. In the region below ?8 °C the charge-sensitive probe oxonol-V has been used to evaluate energy coupling. By using Ca²⁺ to stimulate respiration at 0 °C good results are obtained with ethylene glycol/water alone and optimal results are obtained with a quaternary mixture. A mixture that freezes at ?21 °C gives about 50% inhibition of the respiratory control ratio for electron transport at 0 °C with NADH or succinate as substrates. The mixtures permit low-temperature studies of mitochondrial functions under conditions of minimal respiratory rate, including the kinetics of electron transfer reactions, the formation of intermediate compounds, and the rapid freeze-trapping of mitochondrial reactions for analytical chemistry or ³¹P NMR.     

Ethylene Glycol Utilization,Cold and Ethylene Glycol Shockand Acclimation Proteins in a Psychrotrophic Bacterium

A psychrotrophic Pseudomonas fluorescens was isolated that utilizes ethylene glycol as a sole carbon source, with removal efficiencies of 98% and 96% in 20 and 55 days at 25° and 5°C, respectively. The response of the psychrotroph to environmental shifts was investigated using two-dimensional SDS-PAGE and computing scanning laser densitometry. During a 25°C to 5°C cold shock, the microorganism induced ten cold shock proteins. Under conditions of constant growth at 5°C, five cold acclimation proteins were synthesized. Ethylene glycol shock induced 14 ethylene glycol shock proteins. Ten ethylene glycol acclimation proteins were found. Similarities between the shock proteins and acclimation proteins for cold shock and acclimation and the ethylene glycol shock and acclimation may suggest that these proteins are of significance to both shock recovery as well as constant growth in a new environment.     

Effect of orchard and postharvest application of daminozide on ethylene synthesis by apple fruit

The effects of daminozide (butanedioic acid-2,2-dimethylhydrazide) on ethylene synthesis by apple fruits were investigated. The objective was to determine the effects of postharvest applications as compared to the standard application of diaminozide in the orchard. Immersion in a solution containing 4.25 g L^?1 active ingredient for 5 min delayed the rise in ethylene production in individual “Cox” apples at 15°C by about 2 days, whereas orchard application of 0.85 g L^?1 caused delays of about 3 days. Both modes of application depressed the maximal rate of ethylene production attained by ripe apples by about 30%. Daminozide did not affect the stimulation of respiration by ethylene treatment of “Gloster” apples, but it delayed the increase in ethylene synthesis. Daminozide applied immediately after harvest delayed the rise in ethylene synthesis in “Golden Delicious” held at 15°C, but it was less effective when applied 48 h after harvest or when apples were held at 5°C. Exposure to 1–2 μl L^?1 ethylene for 48 h was less effective in promoting the rise in ethylene in daminozidetreated “Cox” and “Gloster” apples than in untreated fruit. High (100–1000 μl L^?1) concentrations of ethylene more or less overcame the daminozide effect. Apples absorbed about 40% of surface-applied [¹⁴C]daminozide in 48 h, but more than 90% of the radioactivity in the fruit was recovered from the peel and outer 1 cm of the cortex. Daminozide was partly converted to carbon dioxide and other metabolites.     

Participation of GA3, ethylene,NO and HCN in germination of Amaranthus retroflexus L. seeds with various dormancy levels

Amaranthus retroflexus seeds were dormant at 25 °C in the darkness and in the light, and also at 35 °C in the darkness. GA₃ and ethylene partially removed dormancy at 35 °C in the darkness and at 25 °C in the light. Dormancy was removed by 1–5 days of treatment with nitric oxide or cyanide. The effect of NO and HCN was inhibited by cPTIO, thus the effect of HCN was NO dependent. Dry storage for 16 weeks could partially release dormancy only at 35 °C, but not at 25 °C. Dry storage increased the response to light, GA₃ and ethylene. The response to GA₃ and ethylene at 25 °C was enhanced with increasing storage temperature. GA₃, ethylene and nitric oxide could substitute dry storage and stratification in partially dormant seeds.     

Methane fermentation of 2-methoxyethanol by mesophilic digesting sludge

Methane fermentation of 2-methoxyethanol by mesophilic digesting sludge was studied. 2-Methoxyethanol was considered to be degraded through at least two pathways: pathway I, 2-methoxyethanol→methoxyacetate→glycolate→→→methane plus carbon dioxide; pathway II, 2-methoxyethanol→ethylene glycol→ethanol plus acetate→acetate→methane plus carbon dioxide. Optimal pH for complete degradation of 2-methoxyethanol was 7.5. Optimal temperature for consumption of 2-methoxyethanol was 30–35°C. Optimal temperature for accumulation of methoxyacetate was 40°C. The selection of the two pathways depended on pH and temperature.     

Effect of freezing and storage temperature on stability and antimicrobial activity of an antibiotic mixture used for decontamination of tissue allografts

One of the most important risks to be controlled in tissue banking is the infection associated with the clinical use of auto- and allografts. Thus, tissue disinfection protocols are used, in addition to processing in controlled environments. For this purpose, combinations of antibiotics are designed to ensure a broad spectrum of antimicrobial activity. This type of protocol is usually validated by testing its antimicrobial efficacy. In this work, we have studied the effect of several factors on the potential of an antibiotic mixture: container, freezing, storage at 4 °C, storage at ??30 °C and storage at ??80 °C. The molecular stability of the compounds has also been tested, additionally to their efficacy. Our findings show that storage conditions affect the molecular stability of Fungizone and Tobramycin (only in case of frozen storage for the last one). Nevertheless, the solution retains its antimicrobial activity for several weeks. The availability of stored aliquots of disinfectant solution and defining expiry dates for different storage conditions can help to schedule tissue bank tasks.     

Redox potentials in hydro-organic media at normal and subzero temperatures Ferro-ferricyanide and cytochrome c as models

Redox potentials of ferro-ferricyanide and cytochrome c were measured in water/ethylene glycol and water/dimethylsulfoxide (volume ratio from 100/0 to 50/50) between 25 and ?25°C. For both systems, the midpoint potential decreases in the presence of organic solvents and increases by cooling. The magnitude of these variations is larger in dimethylsulfoxide than in ethylene glycol; moreover in the same solvent mixture it is larger with ferro-ferricyanide than with cytochrome c, so that the difference between the redox potentials of these two systems can be strongly affected and even reversed. While in pure water (cacodylate buffer pH 7.0, NaCl 0.1 M) they are respectively +388 and +265 mV, in 50% dimethylsulfoxide at 25°C they decrease to +112 and +208 mV. Reduction of cytochrome c by ferro-ferricyanide, in this mixture, is then expected and was indeed observed. On the other hand, as $\text{(}\text{?E}\text{?T}\text{)}{}^{\mathrm{T}}$, (E being the redox potential) is higher for ferro-ferricyanide than for cytochrome c, the oxidative power of the former for the latter is expected to increase as temperature decreases. This effect was observed in 50% ethylene glycol at ?16°C.Organic solvents and large temperature variations appear then as powerful perturbants of redox reactions. Their effects should be taken into account in studies of redox reactions carried out in cooled hydro-organic media.     

Photosynthetic Rates, Gross Patterns of Carbon Dioxide Assimilation and Activities of Ribulose Diphosphate Carboxylase in Marine Algae Grown at Different Temperatures

Studies of the marine green flagellate Dunaliella tertiolecta have confirmed and extended previous observations of Steemann Nielsen and his colleagues. Algae, grown at 12°C, assimilated carbon dioxide under light-saturated conditions more rapidly than did those grown at 20°C; for both, the assimilation rate being higher at 20°C than at 12°C. Cells grown at the lower temperature contained higher concentrations of soluble protein, higher activities of ribulose diphosphate carboxylase and showed an enhanced relative rate of protein synthesis during the photosynthetic assimilation of carbon dioxide. This appears to represent true adaptation since it allowed the growth rate at 12°C to be almost the same as that at 20°C. Studies of the marine diatom Phaeodactylum tricornutum have not revealed the same picture of temperature adaptation. Cultures grown at 5°C had significantly higher rates of photosynthesis than did those grown at 10°C, but the same was not true when algae grown at 10°C were compared with those grown at 20°C. In this organism, growth at the lower temperatures reduced its ability to photosynthesize at 20°C. Cells grown at the lower temperatures contained more protein than did those grown at 20°C; this was particularly marked in cells growing at 5°C, a temperature which reduced the growth rate. The relative rate of protein synthesis was higher in Phaeodactylum grown at lower temperatures; but this difference was most marked when the measurements were made at 20°C.     

Influence of temperature,ethylene and cyanide on the occurrence of alternative respiration in mitochondria from iris bulbs

Mitochondria, isolated from iris (Iris hollandica cv. Ideal) bulbs that have been treated for early flowering with high temperatures (14 days at 35°C followed by 3 days at 40°C) or with ethylene (10–500 ppm), show an induction of alternative respiratory capacity and a rise in state III respiration. Mitochondria from untreated bulbs (stored at 30°C) do not have an alternative pathway capacity and state III respiration is low. Induction of the alternative respiration by ethylene is maximal after 24 h, while induction by high temperature (> 36°C) is much slower. In the temperature range from 36–40°C, the extent of the induced alternative respiratory capacity increases with higher temperatures. A temperature of 42°C is lethal within 5 days. Bulbs stored at 30°C and 35°C before 40°C treatment reach the same values for alternative respiratory capacity. A treatment of the bulbs with 2.2 mM HCN (30°C) leads to an induction of alternative respiration concomitant with a decrease in state III respiration, after a lag time of 2–3 days. A treatment of 5 days with 2.2 mM HCN or longer is lethal.     

Effects of anaerobiosis on ethylene production, respiration and flowering in iris bulbs

Ethylene production of iris bulbs (Iris hollandica cv. Ideal) was very low. When stored at 30°C, production was 12–20 pmol C₂H₄ (kg fresh weight)^?1 h^?1. Higher temperatures (35°C, 40°C) enhanced the ethylene production; a treatment with 40°C for ca 7 days caused a 3 times higher ethylene production than at 30°. During anaerobic storage (in 100% N₂) ethylene production was equal to that of control bulbs. When after a 7 day period of anaerobiosis the N₂ was replaced by air, a burstlike ethylene production was observed. Twenty-four h after the replacement, ethylene production was equal to control values again. The effects of this production of ethylene on mitochondrial respiration and flowering were investigated. When mitochondria were isolated immediately after the anaerobic treatment (before the enhanced ethylene production) alternative pathway capacity was not detectable, a situation also occurring in control bulbs. When mitochondria were isolated 24 h after the end of the anaerobiosis (after the ethylene burst) uninhibited respiration did not change significantly, but a capacity of the alternative pathway was observed. The increase in alternative pathway capacity after anaerobiosis was partly inhibited by 2,5-norbornadiene (NBD), an ethylene antagonist. Fermentation occurred during anaerobiosis: ethanol concentrations increased during the treatment and decreased when air was supplied. When bulbs were exposed to ethanol vapour the alternative pathway was induced but only when very high ethanol levels in the bulbs were reached. The amount of ethanol accumulated in the bulbs during a 7 day anaerobic treatment was far too low to explain the observed induction of alternative pathway capacity. Flowering percentages were enhanced after a 24 h treatment with ethylene and after a 7 day anaerobic treatment. NBD significantly inhibited the effect of exogenous ethylene and of anaerobiosis on flowering. Ethanol was not able to induce flowering. The burst-like production of ethylene after anaerobiosis probably is responsible for the effects on respiration and flowering.     

A Comparison of Seitz and Millipore Membrane Filters for the Enumeration of Fecal Coliforms

In a comparison of two commonly used membrane filters for enumerating fecal coliform bacteria it was demonstrated that Seitz type M filters recovered statistically more colonies of bacteria than did Millipore HAWG 047S1 filters from pure cultures of Escherichia coli incubated at 44 °C. The membranes were grown on 0.4 % Teepol agar. On incubation at 37°C no significant discrepancy was found. As a reference method was used pour plating in plate count agar (Difco). It was demonstrated that incubation at 44°C did not per se inhibit propagation of fecal coliforms. Both types of filters examined were sterilized by the manufacturers with ethylene oxide. The discrepancy found can therefore not be due to sterilization procedures.     

Resolution and stability of oxazepam enantiomers

A solvent mixture containing dioxane, acetonitrile, and hexane was found to be suitable as a mobile phase to resolve oxazepam enantiomers by chiral stationary phase high performance liquid chromatography using covalent Pirkle columns. The resolved oxazepam enantiomers in this solvent mixture had a racemization half-life greater than 3 days at 23°C. When desiccated at 0°C as dried residue, OX enantiomers were stable for at least 50 days with less than 2% racemization. The conditions which stabilized OX enantiomers significantly facilitated the determination of racemization half-lives of OX enantiomers in a variety of aqueous and nonaqueous solvents and at different temperatures. © 1992 Wiley-Liss, Inc.     

Equilibrium vitrification of mouse embryos at various developmental stages

Previously, we developed a new method by which 2‐cell mouse embryos can be vitrified in liquid nitrogen in a near‐equilibrium state, and then kept at ?80°C for several days. In the present study, we examined whether or not the method was effective for mouse embryos at other developmental stages. Eight‐cell embryos, morulae, and expanded blastocysts of ICR mice were vitrified with ethylene glycol‐based solutions, named EFSc because of their composition of ethylene glycol (30–40%, v/v) and FSc solution. The FSc solution was PB1 medium containing 30% (w/v) Ficoll PM‐70 plus 1.5 M sucrose. The extent of equilibrium was assessed by examining how well vitrified embryos survived after being kept at ?80°C. When 8‐cell embryos and morulae were vitrified with EFS35c or EFS40c and then kept at ?80°C, the survival rate was high even after 4 days in storage and remained high after re‐cooling in liquid nitrogen. On the other hand, the survival of vitrified‐expanded blastocysts kept at ?80°C was low. Therefore, 8‐cell embryos and morulae can be vitrified in a near‐equilibrium state using the same method as for 2‐cell embryos. A high proportion of C57BL/6J embryos at the 2‐cell, 8‐cell, and morula stages vitrified with EFS35c developed to term after transportation on dry ice, re‐cooling in liquid nitrogen, and transfer to recipients. In conclusion, the near‐equilibrium vitrification method, which is effective for 2‐cell mouse embryos, is also effective for embryos at the 8‐cell and morula stages. The method would enable handy transportation of vitrified embryos using dry ice. Mol. Reprod. Dev. 79: 785–794, 2012. © 2012 Wiley Periodicals, Inc.     

Phospholipid vesicle fusion and drug loading: temperature,solute and cholesterol effects,and, a rapid preparation for solute-loaded vesicles

The fusion of sonicated dipalmitoylphosphatidylcholine (DPPC) vesicles was studied by gel-exclusion chromatography as a function of temperature, permeable and impermeable solute concentration, and cholesterol content of the bilayer membrane. Fusion is faster at lower temperatures: there is no fusion at or above 35.5°C (0.10 M DPPC/0.1 M K₂SO₄/0.01 M Hepes buffer (pH 7.4)/0.02% NaN₃). There is about 10% fusion after 1 week at 30°C, and about 60% fusion after 2 days at 13–25°C. Between 13 and 8°C, the fusion product changes from 700-Å-diameter vesicles to the 950-Å vesicles previously reported by Wong et al. (Wong, M., Anthony, F.W., Tillack, T.W. and Thompson, T.E. (1982) Biochemistry 21, 4126–4132). At 1°C, fusion is about 90% complete after 1 day. Membrane-impermeable solutes (NaCl, trehalose and glucose) inhibit fusion in a manner reflecting the total particle concentration. There is no detectable fusion after 3 days (22°C) in either 1.0 M NaCl or 2.0 M sugar, the highest concentrations studied. A suggested explanation is that impermeable solutes osmotically inhibit the influx of solution that accompanies the fusion of vesicles to form a larger vesicle, and, could conceivably thereby inhibit the fusion reaction. By contrast, membrane-permeable solutes (glycerol, ethylene glycol, propylene glycol and ethanol) dramatically increase the fusion rate. 1.0 M ethanol causes 100% fusion in 15–30 min at 22°C. The simultaneous presence of 0.15 M NaCl entirely negates the fusion-promoting effect of 1.0 M ethanol. 1 mol% cholesterol completely inhibits fusion in 0.1 M KCl (20°C), and greatly slows it down either in 1.0 M ethanol at 20°C or in 0.1 M KCl at 4°C. A suggested mechanism is that cholesterol might concentrate in and stabilize bilayer lattice defect sites that are critical for the fusion reaction. The trapping efficiency of vesicles formed by the fast ethanol fusion conditions in the presence of the water-soluble markers, chromate and arsenazo III, ranged from 9.0 to 12.7% of the marker captured in the vesicles, corresponding to trapped volumes of 1.8 to 2.5 1/mol DPPC. Bromophenol blue gave anomalously high values of 67% and 13 1/mol DPPC, which presumably reflect binding, in addition to encapsulation.     

Detection of viable fungal spores contaminant on documents and rapid control of the effectiveness of an ethylene oxide disinfection using ATP assay

Filamentous fungi are able to damage and even destroy archival and library materials. Nowadays the conventional method for detecting such micro‐organisms is to put them in cultures but such methods are laborious and time‐consuming. ATP methodology has been widely applied in other domains and its success on bacteria and yeast has been demonstrated. Several commercial reagent kits are available but they did not give satisfactory results on spores mould. We have elaborated new extraction strategies specific to fungi. A comparison of 42 extraction protocols of ATP from fungal spores was carried out. Extraction at 100°C with DMSO 90% in a Tris–acetate–EDTA buffer proved to be the best method. The viability of cells is estimated by the determination of adenylate energy charge (EC). We applied our method successfully on well‐known species such as Aspergillus flavus, A. niger, A. fumigatus, A. versicolor, Neosartorya fischeri, Eurotium chevalieri, Penicillium chrysogenum, Chaetomium globosum and Ulocladium spp. The results suggest that the ATP bioluminescence assay provides a sensitive and time‐saving method for detecting viable fungal spores. The validity of the procedure was also tested on spores killed by steam and on spores treated with ethylene oxide. We showed that EC determination could be used for a rapid control of the effectiveness of a disinfection process performed with ethylene oxide. Copyright © 2003 John Wiley & Sons, Ltd.     

Temperature effects on ethanol and isopropanol utilization by Candida krusei

Candida Krusei has a optimum growth temperature of 37°C on SASOL ethanol-isopropanol mixture. The organism was unable to grow on isopropanol, but oxidized it partially to acetone in the presence and absence of ethanol. Growth at 40°C in the alcohol mixture was slightly faster than at 30°C over an ethanol concentration range of 0.43 to 3.6% (v/v), although at both temperatures the growth rate declined continuously with increasing concentration. At an ethanol concentration greater than 3.6% (v/v), the mixture was much more inhibitory to growth at 40 and 30°C. The inhibitory effect was due to the ethanol rather than the isopropanol. Metabolites such as acetate, acetaldehyde, and ethyl acetate accumulated in the medium, but the degree of accumulation depended upon the temperature and alcohol mixture concentration. At 40°C, acetaldehyde and acetate accumulated to a greater extent than 30°C on a 4.0% (v/v) synthetic alcohol mixture and this may also cause the greater inhibition at this temperature. The alcohol mixture is unsuitable for single cell protein (SCP) production in batch culture because of the low cell densities observed at all alcohol concentrations.     

Production of an endoinulinase from Aspergillus niger AUMC 9375, by solid state fermentation of agricultural wastes,with purification and characterization of the free and immobilized enzyme

Two different substrates, sunflower (Helianthus annuus L.) tubers and lettuce (Lactuca sativa) roots, were tested. Using a mixture of both wastes resulted in higher production of endoinulinase than either waste alone. Also, ten fungal species grown on these substrates as inexpensive, carbon sources were screened for the best production of endoinulinase activities. Of these, Aspergillus niger AUMC 9375 was the most productive, when grown on the mixture using a 6:1 w/w ratio of sun flower: lettuce, and yielded the highest levels of inulinase at 50% moisture, 30°C, pH 5.0, with seven days of incubation, and with yeast extract as the best nitrogen source. Inulinase was purified to homogeneity by ion-exchange chromatography and gel-filtration giving a 51.11 fold purification. The mixture of sunflower tubers and lettuce roots has potential to be an effective and economical substrate for inulinase production. Inulinase was successfully immobilized with an immobilization yield of 71.28%. After incubation for 2 h at 60°C, the free enzyme activity decreased markedly to 10%, whereas that of the immobilized form decreased only to 87%. A reusability test demonstrated the durability of the immobilized inulinase for 10 cycles and in addition, that it could be stored for 32 days at 4°C. These results indicate that this inulinase, in the immobilized form, is a potential candidate for large-scale production of high purity fructose syrups.     

Response of Amaranthus retroflexus L. seeds to gibberellic acid, ethylene and abscisic acid depending on duration of stratification and burial

Freshly harvested, dormant seeds of Amaranthus retroflexus were unable to germinate at 25 and 35 °C. To release their dormancy at the above temperatures, the seeds were stratified at a constant temperature (4 °C) under laboratory conditions or at fluctuating temperatures in soil or by outdoor burial in soil. Fully dormant, or seeds stratified or buried (2006/2007 and 2007/2008) for various periods were treated with exogenous gibberellic acid (GA₃), ethephon and abscisic acid (ABA). Likewise, the effects of these regulators, applied during stratification, on seed germination were determined. The results indicate that A. retroflexus seed dormancy can be released either by stratification or by autumn–winter burial. The effect of GA₃ and ethylene, liberated from ethephon, applied after various periods of stratification or during stratification, depends on dormancy level. GA₃ did not affect or only slightly stimulated the germination of non-stratified, fully dormant seeds at 25 and 35 °C respectively. Ethylene increased germination at both temperatures. Seed response to GA₃ and ethylene at 25 °C was increased when dormancy was partially removed by stratification at constant or fluctuating temperatures or autumn–winter burial. The response to GA₃ and ethylene increased with increasing time of stratification. The presence of GA₃ and ethephon during stratification may stimulate germination at 35 °C. Thus, both GA₃ and ethylene can partially substitute the requirement for stratification or autumn–winter burial. Both hormones may also stimulate germination of secondary dormant seeds, exhumed in September. The response to ABA decreased in parallel with an increasing time of stratification and burial up to May 2007 or March 2008. Endogenous GA_n, ethylene and ABA may be involved in the control of dormancy state and germination of A. retroflexus. It is possible that releasing dormancy by stratification or partial burial is associated with changes in ABA/GA and ethylene balance and/or sensitivity to these hormones.     

Determining the disinfection of textiles in compressed carbon dioxide using various indicator microbes

Aims: This paper presents a research on the disinfection efficiency of inoculated textile swatches by compressed carbon dioxide, an environmental friendly way to disinfect textiles as opposed to the conventional laundering procedures using water. The disinfection efficiency was determined by using the following microbes inoculated on cotton test fabrics: Enterococcus faecium, Enterobacter aerogenes and Candida albicans. Methods and Results: The experiments were performed using the high pressure extraction device with a maximum pressure of 50 MPa and a small extraction vessel of 500 ml. Pure CO₂ and CO₂ with added disinfection agent or commercial detergent were used. The chosen disinfecting agent was hydrogen peroxide, a widespread disinfecting chemical. It was found that treatment with CO₂ for 25 min at 5 MPa and 40°C (313K) and the addition of 4 ml of specific detergent per litre of CO₂ assures at least a five log step reduction of Enterobacter aerogenes and C. albicans, whilst treatment at 50°C (323K) with CO₂ for 25 min at 5 MPa is sufficient for at least a five log step reduction for Enterococcus faecium. It was also found that a 15‐min CO₂ treatment at 7 MPa and 20°C (293K) was sufficient for the inactivation of the yeast C. albicans, whilst these conditions were not rigorous enough for the challenge bacteria. On the other hand, the labscale treatment with CO₂ for 25 min at pressure 4 and 6 MPa with the addition of detergent or hydrogen peroxide only yields a log step reduction of up to 4 log steps, thus proving the slightly disinfective properties of the CO₂ treatment with added agents, but not reaching efficient results as a 5 log step reduction was not reached. Conclusions: Addition of heat to the compressed CO₂ treatment of textiles inoculated with microorganisms proved more effective than the addition of detergent or disinfectant with compressed CO₂ treatment at temperature of 20°C. Significance and Impact of the Study: CO₂ treatment of textiles is a promising ecological alternative dry‐cleaning method for the disinfection of medical textiles.