Method for estimating bioburden of nonsterile cotton gauze

In new hygienically controlled plants, products often have a low level of microbial contamination, so that current methods for estimating bioburden appear to be inadequate. The adoption of efficient procedures giving consistent and reproducible results could contribute to the improvement of conventional methods for evaluating microbiological quality of products with low bioburden. The effectiveness of a washing procedure and mechanical shaking for the removal of Bacillus subtilis spores from pre-inoculated cotton gauze samples was tested in combination with a membrane filtration technique. A 45-min agitation in the presence of surfactant and glass beads improved recovery up to 70.5%, with satisfactory reproducibility. In order to compare the procedure with the current standard method, uncontaminated samples were processed to extinction by applying a repetitive treatment. When exhaustive rinses were performed in order to calculate a conversion factor, permanent entrapment of a high percentage of organisms in the cotton microfibers was highlighted: this fact may play a role in an overestimation of the extrapolated removal efficiency. Received 18 June 1996/ Accepted in revised form 22 August 1996     

Use of ultrasonic energy in assessing microbial contamination on surfaces

Ultrasonic tanks were evaluated for their ability to remove viable microorganisms from various surfaces for subsequent enumeration. Test surfaces were polished stainless steel, smooth glass, frosted glass, and electronic components. The position of contaminated surfaces in relation to the ultrasonic energy source, distance of the ultrasonic source from the test surfaces, and temperature of the rinse fluid were some of the factors which influenced recovery. Experimental systems included both naturally occurring microbial contamination and artificial contamination with spores of Bacillus subtilis var. niger. The results showed that ultrasonic energy was more reliable and efficient than mechanical agitation for recovering surface contaminants. Conditions which increased the number and percentage of microorganisms recovered by ultrasonic energy were: using a cold rinse fluid, placing the sample bottle on the bottom of the ultrasonic tank, and facing the contaminated surfaces toward the energy source. It was also demonstrated that ultrasonic energy could be effectively used for eluting microorganisms from cotton swabs.     

Use of a Foam Spatula for Sampling Surfaces after Bioaerosol Deposition

The present study had three goals: (i) to evaluate the relative quantities of aerosolized Bacillus atrophaeus spores deposited on the vertical, horizontal top, and horizontal bottom surfaces in a chamber; (ii) to assess the relative recoveries of the aerosolized spores from glass and stainless steel surfaces with a polyester swab and a macrofoam sponge wipe; and (iii) to estimate the relative recovery efficiencies of aerosolized B. atrophaeus spores and Pantoea agglomerans using a foam spatula at several different bacterial loads by aerosol distribution on glass surfaces. The majority of spores were collected from the bottom horizontal surface regardless of which swab type and extraction protocol were used. Swabbing with a macrofoam sponge wipe was more efficient in recovering spores from surfaces contaminated with high bioaerosol concentrations than swabbing with a polyester swab. B. atrophaeus spores and P. agglomerans culturable cells were detected on glass surfaces using foam spatulas when the theoretical surface bacterial loads were 2.88 × 10⁴ CFU and 8.09 × 10⁶ CFU per 100-cm² area, respectively. The median recovery efficiency from the surfaces using foam spatulas was equal to 9.9% for B. atrophaeus spores when the recovery was calculated relative to the theoretical surface spore load. Using a foam spatula permits reliable sampling of spores on the bioaerosol-exposed surfaces in a wide measuring range. The culturable P. agglomerans cells were recovered with a median efficiency of 0.001%, but staining the swab extracts with fluorescent dyes allowed us to observe that the viable cell numbers were higher by 1.83 log units than culturable organisms. However, additional work is needed to improve the analysis of the foam extracts in order to decrease the limit of detection of Bacillus spores and Gram-negative bacteria on contaminated surfaces.Surface sampling is performed on a frequent basis in all situations where clean environment monitoring is needed, e.g., in health care facilities and in the pharmaceutical industry and food industry. An anthrax bioterrorist event in the fall of 2001 has emphasized the importance of efficient sampling methods for detection of pathogenic microorganisms on surfaces within intentionally contaminated locations (22). Unfortunately, our knowledge on the most effective sampling methodology as well as the level of confidence we may have in the results obtained by wiping, swabbing, and other sample collection strategies is still limited (1). Moreover, in most of the studies performed so far, bacteria and/or spores were collected from test samples or coupons of various materials, inoculated with a suspension of microorganisms that had been placed and spread over the surface, and then dried (14, 15). This may not mimic the true situation of surface contamination by a pathogen that has been intentionally released. Edmonds et al. (12) recently reported lower swabbing efficiencies of different types of swab materials used for sampling glass, polycarbonate, and vinyl surfaces contaminated with dry aerosol-deposited Bacillus atrophaeus spores compared to the surfaces inoculated by spore suspensions. Solid surface contamination from exposure to aerosolized spores fits the real world better than the previous models.Therefore, in our study we decided to generate aerosols of various concentrations of B. atrophaeus spores as well as the vegetative cells of Pantoea agglomerans inside a chamber where the bioaerosol particles were allowed to gravitationally settle on solid surfaces. The aerosolization of P. agglomerans was performed to verify the recovery of Gram-negative bacteria according to the recommendations of Budowle et al. (5). The main goal of our study was to establish the range of detection when bioaerosol-contaminated surfaces were swabbed using a commercially available foam spatula.     

The importance of using the optimal plasticware and glassware in studies involving peptides

The unpredictable nature of peptide binding to surfaces requires optimization of experimental containers to be used. To demonstrate the variable recoveries of peptides from multiple surfaces commonly employed in peptide research, we tested the recovery of radiolabeled ¹²⁵I endocrine peptides under different conditions and provide guidelines for determining the surfaces to use for other peptides. ¹²⁵I-labeled peptides (ghrelin, sulfated cholecystokinin-8, corticotropin-releasing factor, glucagon-like peptide-1 [GLP-1], insulin, leptin, nesfatin-1, and peptide YY), representing a wide spectrum in net charge, size, end group, and modification, were incubated for 48 h in glass and plastic tubes untreated or coated with siliconizing fluid. Best surfaces were chosen and peptides were incubated with bovine serum albumin (BSA, 1%) with or without subsequent lyophilization. Recovery of ¹²⁵I-labeled peptides was determined by gamma counting. Important differences in ¹²⁵I-labeled peptide binding capacities to various types of surfaces exist. Siliconization decreased, whereas the addition of BSA improved recovery from surfaces tested. Lyophilizing solutions containing ¹²⁵I-labeled peptides and BSA in the tubes best suited for individual peptides rendered more than 89% recovery for all peptides. Ghrelin specifically displaced ¹²⁵I-ghrelin from borosilicate glass, whereas GLP-1 and Fmoc-arginine did not. Choosing the appropriate experimental container avoids unpredictable peptide loss that results in inaccurate measurements and false conclusions.     

Recovery of bacterial spores dried on aluminium strips

Bacterial spores dried on aluminium strips are used in microbiological validation of packaging and processing systems. Vortex agitation and sonication in Butterfield's buffer, 70% ethanol or 0·1% Tween 80 were evaluated for ease of recovery of bacillus spores dried on aluminium strips to compare the concentration of dried spores to dilutions used to inoculate such strips. The highest recovery for Bacillus subtilis var. globigii spores was observed with sonication in 70% ethanol with average recovery close to the initial inoculum. The highest recovery for B. stearothermophilus spores was with sonication in Butterfield's buffer, averaging 0·8 log less recovery than the initial inoculum. Bacillus subtilis var. globigii spores were recovered from strips in greater numbers than B. stearothermophilus spores for all treatment medium combinations. Scanning electron microscopy revealed unrecovered spores adhering to strips after treatment. Recovery of B. subtilis var. globigii spores decreased with time over the 4 week storage period.     

Forces involved in adhesion of Bacillus cereus spores to solid surfaces under different environmental conditions

H usmark , U. & R önner , U. 1990. Forces involved in adhesion of Bacillus cereus spores to solid surfaces under different environmental conditions. Journal of Applied Bacteriology 69 , 557–562.
The adhesion of Bacillus cereus spores (NCTC 2599) to hydrophobic and hydro-philic glass surfaces was studied when environmental conditions were varied. The spores were exposed in media of different polarities as well as different pH and ionic concentrations. With increasing ethanol concentrations, the polarity of the medium was decreased and the predominant force of attraction was found to be hydrophobic. The spore surface was uncharged at a pH around 3, at which value the spore was most adhesive to both hydrophobic and hydrophilic glass. This could be attributable to the absence of electrostatic repulsion. An increased ionic concentration of the bulk increased the degree of adhesion especially to the hydrophilic surfaces. This indicates the suppression of a solvation barrier at high ionic concentrations, when the polymers of the spore surface become dehydrated.     

Toxoplasma gondii: Purification of zoites from peritoneal exudates by eight methods

Many methods have been proposed for removing contaminating host cells from mouse peritoneal exudates infected with Toxoplasma gondii tachyzoites. Of these, eight established methods were compared. They were density gradients, sonication and trypsin digestion, differential centrifugation, haemolysin digestion, filtration through glass wool and cellulose columns, and sintered glass and polycarbonate filtration. The methods were assessed for zoite recovery, host cell removal, effect on zoite viability and antigenic integrity, time, cost, and ease. They were almost all capable of removing >90% of the mouse leucocytes, but in some cases this resulted in low zoite recoveries. The sonication and trypsin method produced the best zoite recovery and highest purity, but appeared to affect zoite viability and antigenic integrity. The haemolysin digestion procedure has been adopted by our laboratory because of its high recovery of zoites, and it is inexpensive, quick, and easy to perform.     

Forces involved in adhesion of Bacillus cereus spores to solid surfaces under different environmental conditions

The adhesion of Bacillus cereus spores (NCTC 2599) to hydrophobic and hydrophilic glass surfaces was studied when environmental conditions were varied. The spores were exposed in media of different polarities as well as different pH and ionic concentrations. With increasing ethanol concentrations, the polarity of the medium was decreased and the predominant force of attraction was found to be hydrophobic. The spore surface was uncharged at a pH around 3, at which value the spore was most adhesive to both hydrophobic and hydrophilic glass. This could be attributable to the absence of electrostatic repulsion. An increased ionic concentration of the bulk increased the degree of adhesion especially to the hydrophilic surfaces. This indicates the suppression of a solvation barrier at high ionic concentrations, when the polymers of the spore surface become dehydrated.     

Colloidal gas aphrons: A novel approach to protein recovery

Sebba (1987) defined colloidal gas aphrons (CGA) as microbubbles stabilized by surfactant layers, which are created by stirring surfactant solutions at speeds greater than a critical value. A high shear impeller is used for stirring and critical values for the impeller speed must be exceeded to create these stable gas liquid dispersions (typically >5000 rpm). Although there have been no previous reports of direct protein recovery using CGA, it is likely that, with appropriate choice of surfactant, proteins should adsorb to these surfactant bubbles by means of electrostatic and/or hydrophobic interactions. This is the basis of this study, in which the use of CGA for protein recovery from aqueous solution is considered. A surfactant which has been characterized previously for generation of CGA was chosen (Jauregi et al., 1997), i.e., the anionic surfactant sodium bis-(2-ethyl hexyl) sulfosuccinate (AOT). Lysozyme, a well-characterized protein, was chosen as the protein to be recovered. Lysozyme was recovered successfully from aqueous solution using CGA generated from AOT. At optimum conditions, lysozyme recovery, enrichment ratio, and separation ratio were 95%, 19 and 302 respectively, with enzyme activity maintained. These results indicate the exciting potential of this technique. A wide range of process conditions including initial concentration of protein and surfactant, surfactant/protein molar ratio, pH, and ionic strength were considered. High recoveries and enrichments were generally obtained at protein concentrations 0.11 mg/mL. However, at high ionic strength (0.29M) poor separation and recoveries were obtained at low protein concentrations (counter-ions diminishing electrostatic interactions between protein and aphrons at this condition). In general, (ns/np)a was determined to be between 10 and 16 for experiments in which high levels of recovery/separation parameters were found. For most conditions, protein precipitation was observed; however, this precipitate could be resolubilized without loss of enzyme activity.     

Adsorption of Formaldehyde by Various Surfaces During Gaseous Decontamination

Study of the effect of atmospheric relative humity (RH) on the adsorption of paraformaldehyde-generated formaldehyde gas on various surfaces and the effect of the adsorbed formaldehyde on the death rate of bacterial spores showed that increasing the RH caused a corresponding increase of formaldehyde levels on all surfaces. The amount peaked at 83% RH. The levels obtained at 100% RH were slightly below those at 83% RH. Cotton cloth had a much greater affinity for the gas at all RH than either glass or stainless steel. The death rate of bacterial spores on surfaces containing adsorbed formaldehyde was high for the first hour after removal from the formaldehyde atmosphere but decreased rapidly thereafter. This held true for both cotton and glass surfaces. Also, formaldehyde levels of 15 to 27 mug/ml of nutrient broth caused inhibition of bacterial growth, but levels above 27 mug/ml rendered broth sterile.     

Ultrasonic methodology coupled to ATP bioluminescence for the non-invasive detection of fouling in food processing equipment--validation and application to a dairy factory

The use of an ultrasonic apparatus (40 kHz) for the non-destructive, rapid and reproducible removal of biofilm from standard materials (stainless steel and polypropylene) in a dairy factory was investigated. The application of ultrasound with the tested conditions (10 s and 40 kHz) was found not to be detrimental for standard ATP (concentration ranging between 5 x 10(-9) and 10(-5) mol 1(-1)) and for prokaryotic cells, including both rods and coccoid-shaped bacteria (Escherichia coli and Staphylococcus aureus). It allowed the use of the ATP bioluminescence measurement for quantifying the biofilm removal. The repeatability of industrial milk removal was determined on fouled stainless steel and polypropylene sheets. The variability of the results with the sonication method was constant, +/-24% (coefficient of variation) for both surfaces, and was variable with the swabbing method, +/-42% for the stainless steel sheet and +/-74% for the polypropylene sheet. The ultrasonic apparatus removed twice the amount of industrial milk biofilm compared with the swabbing method in the case of the polypropylene sheets. The apparatus was used to validate the industrial cleaning protocols of a milk factory.     

Ultrahigh-throughput screening system for directed polymer binding peptide evolution

Accumulation of plastics in the environment became a geological indicator of the Anthropocene era. An effective reduction of long-lasting plastics requires a treatment with micro-organisms that release polymer-degrading enzymes. Polymer binding peptides function as adhesion promoters and enable a targeted binding of whole cells to polymer surfaces. An esterase A-based Escherichia coli cell surface display screening system was developed, that enabled directed evolution of polymer binding peptides for improved binding strength to polymers. The E. coli cell surface screening system facilitates an enrichment of improved binding peptides from a culture broth through immobilization of whole cells on polymer beads. The polypropylene (PP)-binding peptide liquid chromatography peak I (LCI) was simultaneously saturated at five positions (Y29, D31, G35, E42, and D45; 3.2 million variants) and screened for improved PP-binding in the presence of the anionic surfactant sodium dodecylbenzenesulfonate (LAS; 0.25 mM). The cell surface system enabled efficient screening of the generated LCI diversity (in total ~10 million clones were screened). Characterization of identified LCI binders revealed an up to 12-fold improvement (eGFP-LCI-CSD-3: E42V/D45H) in PP-binding strength in the presence of the surfactant LAS (0.125 mM). The latter represents a first whole cell display screening system to improve adhesion peptides which can be used to direct and to immobilize organisms specifically to polymer surfaces (e.g., PP) and novel applications (e.g., in targeted plastic degradation).     

The Effect of Incubation Temperature on the Recovery of Spores of Bacillus subtilis 8057

S ummary . The recovery of Bacillus subtilis spores was studied after different heat treatments at 95° and incubation at different temperatures in roll tubes in a gradient temperature incubator. Plate count agar and brain–heart infusion agar were used in the roll tubes. Unheated spores showed similar recoveries at 16–48° whereas heated spores had an optimum recovery temperature of c. 30.9. The rate of germination of untreated spores was greatest at c. 41° and ceased at 50°. Heated spores germinated at 52°5°, suggesting that recovery of heat-treated spores is not limited by their ability to germinate. Outgrowth of spores at different incubation temperatures was similar for germinated and ungerminated spores. Accordingly it is outgrowth rather than germination which is sensitive to temperature.     

The measurement of Bacillus mycoides spore adhesion using atomic force microscopy,simple counting methods,and a spinning disk technique

An atomic force microscope has been used to study the adhesion of Bacillus mycoides spores to a hydrophilic glass surface and a hydrophobic-coated glass surface. AFM images of spores attached to the hydrophobic-coated mica surface allowed the measurement of spore dimensions in an aqueous environment without desiccation. The spore exosporium was observed to be flexible and to promote the adhesion of the spore by increasing the area of spore contact with the surface. Results from counting procedures using light microscopy matched the density of spores observed on the hydrophobic-coated glass surface with AFM. However, no spores were observed on the hydrophilic glass surface with AFM, a consequence of the weaker adhesion of the spores at this surface. AFM was also used to quantify directly the interactions of B. mycoides spores at the two surfaces in an aqueous environment. The measurements used "spore probes" constructed by immobilizing a single spore at the apex of a tipless AFM cantilever. The data showed that stretching and sequential bond breaking occurred as the spores were retracted from the hydrophilic glass surface. The greatest spore adhesion was measured at the hydrophobic-coated glass surface. An attractive force on the spores was measured as the spores approached the hydrophobic-coated surface. At the hydrophilic glass surface, only repulsive forces were measured during the approach of the spores. The AFM force measurements were in qualitative agreement with the results of a hydrodynamic shear adhesion assay that used a spinning disk technique. Quantitatively, AFM measurements of adhesive force were up to 4 x 10(3) times larger than the estimates made using the spinning disk data. This is a consequence of the different types of forces applied to the spore in the different adhesion assays. AFM has provided some unique insights into the interactions of spores with surfaces. No other instrument can make such direct measurements for single microbiological cells.     

The physico-chemical characterization of casein-modified surfaces and their influence on the adhesion of spores from a Geobacillus species

To gain a better understanding of the factors influencing spore adhesion in dairy manufacturing plants, casein-modified glass surfaces were prepared and characterized and their effect on the adhesion kinetics of spores from a Geobacillus sp., isolated from a dairy manufacturing plant (DMP) was assessed using a flow chamber. Surfaces were produced by initially silanizing glass using (3-glycidyloxypropyl) trimethoxysilane (GPS) or (3-aminopropyl) triethoxysilane to form epoxy-functionalized (G-GPS) or amino-functionalized glass (G-NH(2)) substrata. Casein was grafted to the G-GPS directly by its primary amino groups (G-GPS-casein) or to G-NH(2) by employing glutaraldehyde as a linking agent (G-NH(2)-glutar-casein). The surfaces were characterised using streaming potential measurements, contact angle goniometry, infrared spectroscopy and scanning electron microscopy. The attachment rate of spores suspended in 0.1?M KCl at pH 6.8, was highest on the positively charged (+14 mV) G-NH(2) surface (333 spores cm(-2) s(-1)) compared to the negatively charged glass (-22 mV), G-GPS (-20 mV) or G-GPS-casein (-21 mV) surfaces (162, 17 or 6 spores cm(-2) s(-1) respectively). Whilst there was a clear decrease in attachment rate to negatively charged casein-modified surfaces compared to the positively charged amine surface, there was no clear relationship between surface hydrophobicity and spore attachment rate.     

Assessment of bioburden on human and animal tissues: Part 1—Results of method development and validation studies

Recovered human and animal tissues are used extensively in surgery for wound repair and reconstruction. In preparation for the validation of chemical disinfection and radiation sterilization processes, studies were performed on the development and validation of quantitative bioburden recovery methods for human bone and soft tissue and also for porcine dermis. The use of a swab-based method was not considered due to the known poor efficiency of recovery for this technique. The “exhaustive extraction” and “inoculated product” approaches to validation of a bioburden recovery efficiency factor have inherent strengths and weaknesses; in this study, tissues were inoculated and also subjected to a series of extractions to determine if/when “exhaustion” occurred. Femoral and tibial shaft rings, iliac crest wedges, sections of Achilles tendon, a soft tissue composite sample, and porcine dermis, were inoculated at several sites with Bacillus atrophaeus spores, and then subjected to either shaking by hand, mechanical shaking, or sonication plus mechanical shaking. Each of these methods of agitation were performed in combination with three rinse (extraction) fluids: phosphate buffer (Butterfield’s buffer), phosphate buffer with 0.2% polysorbate 80 (a surfactant), and water with 1% peptone and 1% polysorbate 80 (Fluid D). The highest recovery efficiencies were observed with sonication plus mechanical shaking; of the three extraction media, Fluid D gave the highest first-rinse recovery efficiency (65%) and Butterfield’s buffer gave the lowest (39%). Each of the three recovery methods, however appeared to reach “exhaustion”, a subsequent rinse giving less than 10% of the recovery found in the first rinse. The results demonstrated the importance of performing bioburden method development and validation studies. The method validation strategy described here, using a combination of tissue inoculation and repetitive extraction, showed the superiority of sonication plus mechanical shaking using Fluid D as the rinse medium. In addition, the use of only the exhaustive extraction approach could have resulted in the development of a methodology that consistently underestimated the bioburden present on/in recovered tissue.     

Characterization of spore surfaces from a Geobacillus sp. isolate by pH dependence of surface charge and infrared spectra

Aims: The surfaces of spores from a Geobacillus sp. isolated from a milk powder production line were examined to obtain fundamental information relevant to bacterial spore adhesion to materials. Materials and Results: The surfaces of spores were characterized using transmission electron microscopy and infrared spectroscopy. Thin sections of spores stained with ruthenium red revealed an exosporium with a hair‐like nap around the spores. Attenuated total reflection infrared spectra of the spores exposed to different pH solutions on a ZnSe prism revealed that pH‐sensitive carboxyl and phosphodiester groups associated with proteins and polysaccharides contributed to the spore’s negative charge which was revealed by our previous zeta potential measurements on the spores. Lowering the pH to the isoelectric point of spores resulted in an increase in intensity of all spectral bands, indicating that the spores moved closer to the zinc selenide (ZnSe) surface as the charged surface groups were neutralized and the spore surface polymers compressed. The attachment of spores to stainless steel was threefold higher at pH 3 compared with pH 7. Conclusions: This research showed that spore attachment to surfaces is influenced by electrostatic interactions, surface polymer conformation and associated steric interactions. Significance and Impact of the Study: The adhesion of thermophilic spores is largely controlled by functional groups of surface polymers and polymer conformation.     

Effects of Different Sizes of Glass Beads on the Release of Sporocysts from Eimeria tenella Oocysts

The oocyst wall is severed by means of mechanical injury or chemical agents. This study reports the percentage of in vitro sporocyst release following mechanical shaking in the presence of varying sizes of glass beads. Glass beads measured 0.5, 1, and 3 mm in diameter and were shaken with the oocysts for different times ranging from 5 sec to 5 min. Approximately 80% of sporocysts were released with 5 min of shaking in the presence of 3 mm glass beads, as well as 30 sec with 0.5 mm beads and 1 mm glass beads. The release of sporocysts of E. tenella was most efficient using 1 mm glass beads and treatment times of 30 sec to 1 min. Therefore, the use of 1 mm glass beads with 30 sec to 1 min of agitation is recommended in order to maximize sporocyst release and recovery and to improve the yield of viable sporozoites for use in biochemical, tissue culture, and immunological applications of coccidia.     

Comparison of Media for the Enumeration of Clostridium perfringens

For the enumeration of viable vegetative cells and spores of Clostridium perfringens, noncommercial (laboratory prepared) sulfite-polymyxin-sulfadiazine (SPS) agar, tryptone-sulfite-neomycin (TSN) agar, and Shahidi-Ferguson-perfringens (SFP) agar were statistically compared to SPS agar without antibiotics. The selectivities of these four media were also evaluated on the basis of their ability to inhibit the growth of pure cultures of a variety of other organisms. The average recovery of vegetative cells of 10 strains of C. perfringens with SFP agar was not significantly higher than with SPS agar with 10(4) organisms per g, but with 10(6) organisms per g it yielded significantly higher recoveries than SPS agar. TSN agar yielded significantly lower recoveries at both inoculum levels. SFP agar gave significantly higher recoveries of spores than SPS and TSN agars. Average plate counts of spores in SFP agar were 75% as high as in SPS agar without antibiotics, but only 45% of the spores grew in SPS agar and 25% in TSN agar. TSN agar was the most selective of the three media, but the selectivity of SPS agar approached that of TSN agar under the test conditions. SFP agar, which was the least selective of the media, allowed growth to some extent of nearly all of the facultative anaerobes tested.     

Recovery of Pseudocercosporella herpotrichoides Spores from Rain-Splash Samples

Methods for recovery of P. herpotrichoides spores from rain-splash were tested, initially with pure spore suspensions and then with field samples. Provided surfactant was added and samples were processed immediately, centrifugation gave good recovery or spores from field samples which contained few soil particles. Foam-flotation, glycerol and sucrose methods for separation of spores from soil particles were not satisfactory for P. herpotrichoides spores. A paraffin oil method proved to be the most reliable because it gave good recovery of P. herpotrichoides spores from field samples containing many soil particles.