Identification of Possible Artifacts in the Association of Official Analytical Chemists Sporicidal Test

Two laboratories tested four different brands of alkaline 2% glutaraldehyde sterilants by the Association of Official Analytical Chemists sporicidal test. Each laboratory found survival of Clostridium sporogenes spores on spore-labeled unglazed porcelain penicylinders (cylinders) to vary from test to test, and survival did not always correlate with increasing sterilant exposure time. These results were consistent with a theory that there may be random conditions within the test that prevent the sterilant from contacting all spores. Further studies indicated that the prior history of the unglazed porcelain cylinders and whether the C. sporogenes culture grown in egg-meat media had been processed (homogenized) to eliminate visible pieces of egg-meat media were important factors affecting the results and repeatability of this test.     

Decontamination of a hard surface contaminated with Bacillus anthracisΔSterne and B. anthracis Ames spores using electrochemically generated liquid-phase chlorine dioxide (eClO2)

Aims: To evaluate the inactivation of Bacillus anthracisΔSterne and Ames spores using electrochemically generated liquid‐phase chlorine dioxide (eClO₂) and compare two sporulation and decontamination methods with regard to cost, safety and technical constraints. Methods and Results: Spores were prepared via agar and broth methods and subsequently inoculated and dried onto clean, autoclave‐sterilized glass coupons. Bacillus anthracis spore inactivation efficacy was evaluated using the modified three‐step method (AOAC 2008.05) and a single‐tube extraction method. Spores (7·0 ± 0·5 logs) were inactivated within 1 min at room temperature using freshly prepared eClO₂. Bacillus anthracisΔSterne spores decreased in size after eClO₂ treatment as measured using a Beckman Coulter Multisizer. Conclusions: eClO₂ saturation of a hard surface was an effective B. anthracis sporicide. Broth sporulation and the single‐tube extraction method required less time and fewer steps, yielded a higher percentage of phase‐bright spores and showed higher spore recovery efficiency compared with AOAC 2008.05, making it more amenable to biosafety level 3 (BSL3) testing of virulent spores. Significance and Impact of the Study: Two test methods demonstrated the sporicidal efficacy of eClO₂. A new single‐tube extraction test protocol for decontaminants was introduced.     

Effect of methodology, dilution, and exposure time on the tuberculocidal activity of glutaraldehyde-based disinfectants

The Association of Official Analytical Chemists (AOAC) test for assessing the tuberculocidal activity of disinfectants has been shown to be variable. A modified AOAC test, which substituted Middlebrook 7H9 broth as the primary subculture medium and used neutralization by dilution, was compared with the standard AOAC method to assess the mycobactericidal activity of three glutaraldehyde-based disinfectants at 20 degrees C and various exposure times. These changes had a marked effect on results, with the modified AOAC test providing more positive penicylinders per 10 replicates in 12 of the 13 comparisons that provided positive results. These differences were observed with both Mycobacterium bovis (ATCC 35743) and a clinical isolate of Mycobacterium tuberculosis. The effects of various exposure times to and dilutions of the glutaraldehyde-based disinfectants were also examined. The minimum exposure time needed to inactivate reliably M. bovis or M. tuberculosis with 2% glutaraldehyde was 20 min at 20 degrees C. Diluting 2% glutaraldehyde caused a significant decline in mycobactericidal activity. Modification of the standard AOAC test to improve its sensitivity in detecting the failure of disinfectants to inactivate mycobacteria is indicated.     

Effect of methodology, dilution, and exposure time on the tuberculocidal activity of glutaraldehyde-based disinfectants.

The Association of Official Analytical Chemists (AOAC) test for assessing the tuberculocidal activity of disinfectants has been shown to be variable. A modified AOAC test, which substituted Middlebrook 7H9 broth as the primary subculture medium and used neutralization by dilution, was compared with the standard AOAC method to assess the mycobactericidal activity of three glutaraldehyde-based disinfectants at 20 degrees C and various exposure times. These changes had a marked effect on results, with the modified AOAC test providing more positive penicylinders per 10 replicates in 12 of the 13 comparisons that provided positive results. These differences were observed with both Mycobacterium bovis (ATCC 35743) and a clinical isolate of Mycobacterium tuberculosis. The effects of various exposure times to and dilutions of the glutaraldehyde-based disinfectants were also examined. The minimum exposure time needed to inactivate reliably M. bovis or M. tuberculosis with 2% glutaraldehyde was 20 min at 20 degrees C. Diluting 2% glutaraldehyde caused a significant decline in mycobactericidal activity. Modification of the standard AOAC test to improve its sensitivity in detecting the failure of disinfectants to inactivate mycobacteria is indicated.     

An evaluation of the sporicidal activity of ozone.

This study was undertaken to determine the feasibility of sterilizing surfaces with ozone-saturated water by the methods of the Association of Official Analytical Chemists (AOAC). Initially, it was determined that there was no apparent difference in ozone resistance between spores of Bacillus subtilis and Clostridium sporogenes when they are suspended in water. Both species were inactivated by a 10-min exposure at ambient temperature. Resistance was increased when the spores were dried on AOAC carriers. Viable organisms were recovered after an exposure of 40 min at ambient temperature. An increase in the reactor water temperature to 60 degrees C did not improve the effectiveness of the ozone in sterilizing AOAC carriers. Dried spores of C. sporogenes were more resistant than B. subtilis spores because of a greater accumulation of organic matter on the carriers. No significant sporicidal activity was demonstrated after 40 min for spores of either species when they were inoculated on silk suture loops. The data suggest that organic loading and poor ozone penetrability are key factors in effecting the ability of ozone to sterilize surfaces rapidly.     

An evaluation of the sporicidal activity of ozone

This study was undertaken to determine the feasibility of sterilizing surfaces with ozone-saturated water by the methods of the Association of Official Analytical Chemists (AOAC). Initially, it was determined that there was no apparent difference in ozone resistance between spores of Bacillus subtilis and Clostridium sporogenes when they are suspended in water. Both species were inactivated by a 10-min exposure at ambient temperature. Resistance was increased when the spores were dried on AOAC carriers. Viable organisms were recovered after an exposure of 40 min at ambient temperature. An increase in the reactor water temperature to 60 degrees C did not improve the effectiveness of the ozone in sterilizing AOAC carriers. Dried spores of C. sporogenes were more resistant than B. subtilis spores because of a greater accumulation of organic matter on the carriers. No significant sporicidal activity was demonstrated after 40 min for spores of either species when they were inoculated on silk suture loops. The data suggest that organic loading and poor ozone penetrability are key factors in effecting the ability of ozone to sterilize surfaces rapidly.     

An effective iodide formulation for killing Bacillus and Geobacillus spores over a wide temperature range

AIMS: To develop a sporicidal reagent which shows potent activity against bacterial spores not only at ambient temperatures but also at low temperatures. METHODS AND RESULTS: Suspension tests on spores of Bacillus and Geobacillus were conducted with the reagent based on a previously reported agent (N. Kida, Y. Mochizuki and F. Taguchi, Microbiology and Immunology 2003; 47: 279-283). The modified reagent (tentatively designated as the KMT reagent) was composed of 50 mmol l(-1) EDTA-2Na, 50 mmol l(-1) ferric chloride hexahydrate (FeCl(3).6H(2)O), 50 mmol l(-1) potassium iodide (KI) and 50% ethanol in 0.85% NaCl solution at pH 0.3. The KMT reagent showed significant sporicidal activity against three species of Bacillus and Geobacillus spores over a wide range of temperature. The KMT reagent had many practical advantages, i.e. activity was much less affected by organic substances than was sodium hypochlorite, it did not generate any harmful gas and it was stable for a long period at ambient temperatures. The mechanism(s) of sporicidal activity of the KMT reagent was considered to be based on active iodine species penetrating the spores with enhanced permeability of the spore cortex by a synergistic effect of acid, ethanol and generated active oxygen. CONCLUSIONS: The data suggest that the KMT reagent shows potent sporicidal activity over a wide range temperatures and possesses many advantages for practical applications. SIGNIFICANCE AND IMPACT OF THE STUDY: The results indicate development of a highly applicable sporicidal reagent against Bacillus and Geobacillus spores.     

COMPARISON OF MODIFIED SALMONELLA-TEK ENZYME IMMUNOASSAY AND MODIFIED GENE-TRAK SALMONELLA ASSAY FOR RECOVERY OF SALMONELLA FROM SELECTED LOW-MOISTURE FOODS

The sensitivity of the original versus the modified Salmonella-Tek enzyme immunoassay (EIA) was compared for recovery of Salmonella spp. from selected low-moisture foods. Serial tenfold dilutions were inoculated into incubated post enrichment media (dilution-to-extinction approach). Results indicated no significant difference between the original and modified Salmonella-Tek EIAs. A comparison of the modified Salmonella-Tek EIA and the modified GENE-TRAK Salmonella assay, using the same approach, also showed no significant differences.
The effectiveness of the assays was then compared using a second approach (dry bulk inoculation). A lyophilized culture was inoculated into bulk food. Replicate 25-g test portions were used in a 3-way comparison of the effectiveness of the modified Salmonella-Tek EIA, the modified GENE-TRAK Salmonella assay, and the standard culture method approved by the Association of Official Analytical Chemists (AOAC) International and recommended in the Food and Drug Administration's Bacteriological Analytical Manual. Of 460 test portions examined, 307 gave positive reactions with the modified Salmonella-Tek EIA, 298 with the modified GENE-TRAK Salmonella assay, and 292 with the AOAC/BAM culture method.     

Viability of Bacillus subtilis Spores in Rocket Propellants

The sporicidal activity of components used in liquid and solid rocket propellants was tested by use of spores of Bacillus subtilis dried on powdered glass. Liquid propellant ingredients tested were N₂O₄, monomethylhydrazine and 1,1-dimethylhydrazine. N₂O₄ was immediately sporicidal; the hydrazines were effective within several days. Solid propellants consisted of ammonium perchlorate in combination with epoxy resin (EPON 828), tris-1-(2-methyl) aziridinyl phosphine oxide, bis-1-(2-methyl) aziridinyl phenylphosphine oxide, and three modified polybutadiene polymers. There was no indication of appreciable sporicidal activity of these components.     

Quantitative Method To Determine Sporicidal Decontamination of Building Surfaces by Gaseous Fumigants,and Issues Related to Laboratory-Scale Studies

Chlorine dioxide gas and vaporous hydrogen peroxide sterilant have been used in the cleanup of building interiors contaminated with spores of Bacillus anthracis. A systematic study, in collaboration with the U.S. Environmental Protection Agency, was jointly undertaken by the U.S. Army-Edgewood Chemical Biological Center to determine the sporicidal efficacies of these two fumigants on six building structural materials: carpet, ceiling tile, unpainted cinder block, painted I-beam steel, painted wallboard, and unpainted pinewood. Critical issues related to high-throughput sample processing and spore recovery from porous and nonporous surfaces included (i) the extraction of spores from complex building materials, (ii) the effects of titer challenge levels on fumigant efficacy, and (iii) the impact of bioburden inclusion on spore recovery from surfaces and spore inactivation. Small pieces (1.3 by 1.3 cm of carpet, ceiling tile, wallboard, I-beam steel, and pinewood and 2.5 by 1.3 cm for cinder block) of the materials were inoculated with an aliquot of 50 μl containing the target number (1 × 10⁶, 1 × 10⁷, or 1 × 10⁸) of avirulent spores of B. anthracis NNR1Δ1. The aliquot was dried overnight in a biosafety cabinet, and the spores were extracted by a combination of a 10-min sonication and a 2-min vortexing using 0.5% buffered peptone water as the recovery medium. No statistically significant drop in the kill efficacies of the fumigants was observed when the spore challenge level was increased from 6 log units to 8 log units, even though a general trend toward inhibition of fumigant efficacy was evident. The organic burden (0 to 5%) in the spore inoculum resulted in a statistically significant drop in spore recovery (at the 2 or 5% level). The effect on spore killing was a function of the organic bioburden amount and the material type. In summary, a high-throughput quantitative method was developed for determining the efficacies of fumigants, and the spore recoveries from five porous materials and one nonporous material ranged between 20 and 80%.Biological terrorism has become a major concern in the United States since the anthrax spore-tainted letters in the fall of 2001 resulted in contamination and closure of the U.S. Postal Service Curseen-Morris Processing and Distribution Center (Brentwood Post Office), the Hart Senate Office Building, and the American Media Inc. office building in Boca Raton, FL. The contamination of infrastructure posed an unprecedented challenge of decontaminating over 20,000,000 cubic feet (∼1 million sq. ft.) of combined building interior space (6). The incident required concerted action from the government of the United States and the private sector to develop technologies for building interior cleanup. A number of liquid (29) and gaseous (3) products were granted crisis exemptions under the Federal Insecticide, Fungicide, and Rodenticide Act by the U.S. Environmental Protection Agency (EPA) for use as sterilants against Bacillus anthracis spores, but their application and efficacy in the context of large three-dimensional spaces and complex building material surfaces were not fully understood. No products were (or currently are) registered for use in such applications, involving large volumes and complex (porous and nonporous) structural building materials.In early 2005, a systematic study of laboratory-scale decontamination of five porous surfaces (carpet, ceiling tile, cinder block, painted wallboard, and unpainted wood) and one nonporous surface (painted I-beam steel) was initiated by the U.S. EPA in collaboration with the U.S. Army Edgewood Chemical Biological Center (ECBC). The overall objective of this collaborative study was to systematically investigate the abilities of fumigants to effectively decontaminate building materials contaminated with anthrax spores. This unprecedented systematic investigation involved the determination of efficacy (or log reduction in the number of viable spores) as a function of fumigant technology, technology operating parameters (e.g., fumigant concentration and exposure time), environmental conditions (temperature and relative humidity [RH]), and building material types. The magnitude and scope of this study required that new methods be developed to incorporate the use of complex materials in sporicidal efficacy testing and the processing of an unprecedented number of complex samples.Current standardized sporicidal test methods include the Association of Official Analytical Chemists (AOAC International) sporicidal activity of disinfectant test (AOAC Official Method 966.04) (4) and the American Society for Testing and Materials (ASTM) 2414-05 (3) and quantitative carrier test (QCT) (2). All of these methods are based on testing hard-surface carrier-based spores, which are submerged in a disinfectant for a desired contact time, followed by the addition of a neutralizer and enumeration of viable spores recovered from the carrier. Almost all standard test methods for liquid disinfectants use small coupons, e.g., 5- by 5-mm squares or 1-cm discs, on which 1 million to 10 million (6 to 7 log) spores are inoculated. While AOAC Official Method 966.04 is qualitative, the other two test methods are quantitative and provide log reduction estimates. Currently, demonstration of a >6-log-unit inactivation of B. anthracis or an appropriate surrogate spore (e.g., Bacillus subtilis) using a quantitative test method, such as QCT, which is also known as ASTM 2197-02, or the three-step method (TSM), also known as ASTM 2414-05, by a decontaminant is a requirement for product registration as a sporicidal agent against spores of B. anthracis Ames (18).Key information on three critical issues was lacking at the start of this study. First, optimal spore extraction protocols that could be scaled to process over 200 samples per run (or day) were lacking. Second, the appropriate spore challenge level for fumigation studies was unknown, even though a range between 5 and 8 log spores/coupon has been used in a number of recent disinfection studies (12, 13, 14, 16, and 17). Finally, it was not known if protein serum (an organic burden is included in standard procedures, such as AOAC Official Method 966.04) should be included in the testing performed with the fumigants. The specific objectives of this study, therefore, were to (i) develop scalable coupon-processing/spore extraction protocols from six building materials that would result in recovery of >20% of the spores inoculated per coupon, (ii) investigate the effects of three spore challenge levels on spore extraction and the efficacy of chlorine dioxide (CD) gas and vaporous hydrogen peroxide (VHP), and, finally, (iii) investigate the effect of organic burden inclusion on spore recovery and sterilization using CD gas.     

Vapor-phase hydrogen peroxide as a surface decontaminant and sterilant.

The feasibility of utilizing vapor-phase hydrogen peroxide (VPHP) as a surface decontaminant and sterilant was evaluated in a centrifuge application. The prototype VPHP decontamination system, retrofitted into a Beckman L8-M ultracentrifuge, was designed to vaporize a 30% (wt/wt) solution of aqueous hydrogen peroxide continuously injecting and withdrawing VPHP in a deep-vacuum flow-through system. VPHP cycles of 4, 8, 16, and 32 min were examined for cidal activity against spores of Bacillus subtilis subsp. globigii and Bacillus stearothermophilus. Spore inocula (approximately 10(6)/coupon) were dried onto 0.5-in. (1.27-cm)-square stainless-steel coupons, and coupons were suspended in the centrifuge chamber, the space between the refrigeration can and the barrier ring (inner gap), and the space between the barrier ring and the vacuum ring (outer gap). At a chamber temperature of 4 degrees C, B. subtilis subsp. globigii spores were inactivated within 8 min, while inactivation of spores located in the outer gap at 27 degrees C required 32 min. The elevated temperature and high surface area/volume ratios in the outer gap may serve to decompose the gas more rapidly, thus reducing cidal efficacy. Of the two test spores, B. stearothermophilus was more resistant to VPHP. Nonetheless, VPHP was shown to possess significant sporicidal capability. For practical decontamination applications of the type described, VPHP shows promise as an effective and safer alternative to currently used ethylene oxide or formaldehyde vapors.     

Vapor-phase hydrogen peroxide as a surface decontaminant and sterilant

The feasibility of utilizing vapor-phase hydrogen peroxide (VPHP) as a surface decontaminant and sterilant was evaluated in a centrifuge application. The prototype VPHP decontamination system, retrofitted into a Beckman L8-M ultracentrifuge, was designed to vaporize a 30% (wt/wt) solution of aqueous hydrogen peroxide continuously injecting and withdrawing VPHP in a deep-vacuum flow-through system. VPHP cycles of 4, 8, 16, and 32 min were examined for cidal activity against spores of Bacillus subtilis subsp. globigii and Bacillus stearothermophilus. Spore inocula (approximately 10(6)/coupon) were dried onto 0.5-in. (1.27-cm)-square stainless-steel coupons, and coupons were suspended in the centrifuge chamber, the space between the refrigeration can and the barrier ring (inner gap), and the space between the barrier ring and the vacuum ring (outer gap). At a chamber temperature of 4 degrees C, B. subtilis subsp. globigii spores were inactivated within 8 min, while inactivation of spores located in the outer gap at 27 degrees C required 32 min. The elevated temperature and high surface area/volume ratios in the outer gap may serve to decompose the gas more rapidly, thus reducing cidal efficacy. Of the two test spores, B. stearothermophilus was more resistant to VPHP. Nonetheless, VPHP was shown to possess significant sporicidal capability. For practical decontamination applications of the type described, VPHP shows promise as an effective and safer alternative to currently used ethylene oxide or formaldehyde vapors.     

Sporicidal Activity of Peracetic Acid and β-Propiolactone at Subzero Temperatures

A method was developed to evaluate and measure the sporicidal activity of peracetic acid (PAA) and beta-propiolactone (BPL) at subzero temperatures as low as -40 C. Bacillus subtilis var. niger spores were used as the test organism. Both PAA and BPL were sporicidal at low temperatures, with PAA the more active. The temperature coefficients of the two chemicals are generally low over a range of 20 to -20 C, but increase significantly at temperatures below this. Results showed an initial lag in the PAA death rates that was directly dependent on the temperature. BPL did not show this lag time.     

Sporicidal Activity of Peracetic Acid and β-Propiolactone at Subzero Temperatures

A method was developed to evaluate and measure the sporicidal activity of peracetic acid (PAA) and β-propiolactone (BPL) at subzero temperatures as low as -40 C. Bacillus subtilis var. niger spores were used as the test organism. Both PAA and BPL were sporicidal at low temperatures, with PAA the more active. The temperature coefficients of the two chemicals are generally low over a range of 20 to -20 C, but increase significantly at temperatures below this. Results showed an initial lag in the PAA death rates that was directly dependent on the temperature. BPL did not show this lag time.     

An effective sporicidal reagent against Bacillus subtilis spores

We developed a reagent which showed significant sporicidal activity against Bacillus subtilis spores. This reagent was composed of ethylenediaminetetraacetic acid, disodium salt (EDTA-2Na), ferric chloride hexahydrate (FeCl3 x 6H2O) and ethanol (tentatively designated as the ethanol reagent). The ethanol reagent showed pH- and temperature-dependent sporicidal activity. At pH 0.3, its activity was almost the same as that of 0.05% sodium hypochlorite at 20 C and was higher at 37 C than at 20 C. The activity of the ethanol reagent was similar both with and without 10% serum. The ethanol reagent might be applicable for disinfecting Bacillus spores.     

Susceptibility of Clostridium Sporogenes Spores to Selected Reference Substances and Disinfectants

Research on the susceptibility of the spores of anaerobic bacteria such as Clostridium sporogenes or Clostridioides difficile is vital for assessing the sporicidal activity of disinfectants. The diverse susceptibility of anaerobic bacteria spores may lead to different disinfection parameters being determined by laboratories that prepare spore suspensions to test sporicidal effectiveness. The tests were performed using the suspension method according to PN-EN 13704:2018-09. In order to assess the susceptibility of the C. sporogenes spores, the criterion established for the C. difficile ribotype 027 spores was used in accordance with PN‑EN 17126:2019-01. The susceptibility of the C. sporogenes spores to glutardialdehyde corresponded to the susceptibility ranges established for the C. difficile ribotype 027 spores. The C. sporogenes spore suspension was susceptible to low concentrations of peracetic acid (0.01%). A disinfectant containing peracetic acid as the active substance showed high sporicidal activity at a low concentration (1%), a short contact time (15 minutes), and a high organic load (3.0 g/l bovine albumin + 3.0 ml/l sheep erythrocytes), as compared to a disinfectant with glutardialdehyde, which was sporicidal at a higher concentration (2.5%), at a longer contact time(60 minutes) and lower organic conditions (3.0 g/l bovine albumin). There is a need to define the minimum susceptibility criteria for the C. sporogenes spores to the reference substances most often found in disinfectants with sporicidal activity. Excessive susceptibility of the C. sporogenes spores to reference substances may result in low-performance parameters of disinfection products with sporicidal activity and lead to ineffective disinfection in practice. Open in a separate window     

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.     

Assesssment of sporicidal efficacy

On the basis of their activity against bacterial spores, chemical agents can be divided into two groups: Group A contains chemicals that are bactericidal and sporistatic but not sporicidal, e.g. phenols, cresols, parabens, quaternary ammonium compounds and biguanides; Group B contains those, such as glutaraldehyde, chloride-releasing agents, ethylene oxide and hydrogen peroxide, that show both bactericidal and sporicidal activity, although much higher concentrations may be needed to achieve the latter effect.Sporistatic activity can be examined by various methods, e.g. (i) determining minimum inhibitory concentrations, (ii) detecting by phase-contrast microscopy the concentrations needed to inhibit germination or outgrowth, (iii) measuring spectrophotometrically effects on germination or outgrowth. Information thereby obtained is of considerable importance in food microbiology. Sporicidal efficacy can be tested against spores in liquid medium or suspended on appropriate carriers. Factors influencing activity such as concentration, pH, temperature and the presence of organic matter need to be assessed. The principles of evaluating sporicidal activity are essentially the same as for determining bactericidal activity. The main difference is that a treated spore has to pass through complex stages (germination and outgrowth) before a vegetative cell, and eventually a colony, is produced, if a conventional counting method is employed. It is essential that adequate quenching of residual activity is achieved and that recovery conditions are such as to permit viable but damaged spores the opportunity to revive. A recently developed procedure utilises bioluminescence as a means of determining sporicidal efficacy.     

Elimination and molecular identification of endophytic bacterial contaminants during in vitro propagation of <Emphasis Type="Italic">Bambusa balcooa</Emphasis>

Bambusa balcooa is an economically important, multipurpose bamboo species, decidedly used in construction industry. Availability of natural bamboo is depleting very rapidly due to accelerated deforestation and its unrestrained use. The large number and timely supply of saplings are the need of the hour for the restoration of bamboo stands. Micropropagation, being the potent alternative for season independent rapid regeneration, is restricted in bamboo because of endophytic contamination. An in vitro attempt has been taken to overcome the endophytic contamination by using broad spectrum antibiotics as surface sterilant as well as a media component. Ampicillin sodium salt (5 mg/ml for 30 min) as a surface sterilant was found as the best treatment for high bud breaking (80%) coupled with high branching and low contamination (20%) but it was found ineffective to control the contamination during multiplication stage. Then, two endophytes were isolated and minimum inhibitory concentration was determined through antibiotic susceptibility test for successful eradication at multiplication stage. Finally, contamination free cultures were obtained when streptocycline (100 μg/ml) and gentamicin sulphate (75 μg/ml) were added into the medium. The two isolated endophytes, BB1 and BB2, were identified through 16S rDNA techniques and NCBI-BLAST algorithm with 99% sequence similarity with those of Janibacter sp. (KX423734) and Serratia marcescens strain (KX423735). To our knowledge, this is the first report for B. balcooa where antibiotics were used as surface sterilant as well as medium component, to control endophytic bacterial contaminants, followed by their identification.     

A suspension method to determine reuse life of chemical disinfectants during clinical use

In-use testing of disinfectants is necessary to ensure efficacy over time. The current official procedure for testing disinfectants, the Association of Official Analytical Chemists (AOAC) use-dilution method, cannot be adapted to repeated sampling techniques of use-life testing. It is therefore necessary to use an alternative method when evaluating the activity of a disinfectant under actual use. The Clinical Research Associates (CRA) suspension method was developed to fill this need. It consists of adding 0.5 ml of a standard culture to 5.0 ml of test disinfectant and sampling the mixture after 10 min for surviving bacteria. When this test was compared with the AOAC use-dilution method under a simulated use situation, the two methods were generally equivalent in identifying disinfectant inactivation. In addition, the CRA method was less time consuming, easier to perform, and less variable than the AOAC method. Use of the CRA method in a clinical study demonstrated the need for reuse claims to be based on clinical use studies rather than on laboratory testing only.