Transcript Micro PRO
Advanced Analytical Micro PRO™ Overview of Today’s Presentation • • • • History of Advanced Analytical Technologies, Inc. How the Technology Works The Micro PRO™ System Micro PRO™ Applications and Results • • • Qualitative Analysis – Presence/Absence Quantitative Analysis – Enumeration Customer Presentations Advanced Analytical Improving Process Empowering Progress OUR MISSION Through innovative technology and collaborative relationships we will: > Deliver superior customer support, services, and solutions > Create sustainable growth > Foster a dynamic and fulfilling work environment Advanced Analytical Technologies, Inc. Who are We? • History: Founded 1997, 4 Scientific Co-founders Acquired CE Technology December, 2006 Privately Funded • Business: Rapid Microbial Detection Technology Capillary Electrophoresis Technology • Markets: Pharmaceutical, Personal Care Products, Fermentation, Environmental • Microbiology Solution: Replace current microbial detection methods (requiring 24h – 5 days) with a technician-friendly, rapid system capable of detection and enumeration • Products: Micro PRO™ Instrument, Micro PRO™ Media Kit, Micro PRO™ Reagent Kit, TVO Kit Basics of Flow Cytometry Basics of Flow Cytometry • Laser-based irradiation of cells • Fluorochromes bound to cells provide information on cell state (e.g., live, dead, spores, vegetative) • Light scattering provides relative size information • System composed of fluidic, optic and electronic components • Advantages: Rapid and quantitative analysis of individual cells Flow Cytometry: Fluidics Sample delivery Sample delivery Labeled bacteria Sheath delivery Sheath flow Core flow • Quantitative cell delivery • Hydrodynamic Focusing • Single File Passage through detection region Flow Cytometry: Optics Labeled microbial cell Scatter Detector Fluorescence Detector Scatter signal Fluorescence signal High performance optical filters Fluorescence plus Scatter = One Count Laser Beam – shaped and focused; 635 nm laser excitation Flow Cytometry: Optics Unlabeled Particle Scatter Detector Fluorescence Detector Scatter signal High performance optical filters Scatter without Fluorescence = No Count Laser Beam – shaped and focused; 635 nm laser excitation Electronics • Signal processing component • The Micro PRO™ triggers on fluorescence • Fluorescent event above the threshold is processed, along with the corresponding scatter event, and is plotted and recorded as a count = 1 count Detector output = 0 count Time Fluorescence Threshold Level Signal Processing cumulative Microbe A Microbe A + B Microbe A + B +C Interpretation of intensity plots Cell size Amount of label Setting Analysis Boxes Fluorescence Intensity vs. Counts Intensity Plot Scatter Intensity vs. Counts Box = 166856 counts/mL 99.2% of the counts are in the box Micro PRO™ INSTRUMENTATION Introducing the Micro PRO™ Automated, High-Throughput Analysis • Qualitative analysis (Presence/Absence) 20 samples/hour • Quantitative analysis (Enumeration) 15 samples/hour • Holds up to 42 samples at once • Automatically • adds up to 3 reagents • mixes samples • cleaning and bubble removal The Micro PRO™ Additional Advantages • Qualitative Analysis – Presence/Absence • Product Testing – Finished, raw materials, in-process samples • Screen products for bacteria, yeast & mold in 1 test • Next day results for product release • Quantitative Analysis – Enumeration • Purified/process water monitoring • Surface swab analysis • Pure culture enumeration • Validation packages & services available Analysis on the Micro PRO™ 1 Load sample vials and syringes 3 Reagent additions and sample injection performed automatically as defined in the Method 2 Select Tray Setup Micro PRO™ Output: Pass/Fail & Counts/mL 4 The Micro PRO™ Hardware upgrades • High sample throughput • • • • Qualitative analysis = 20 samples/hour (3min/sample) Quantitative analysis = 15 samples/hour (4min/sample) Preparation of multiple samples at a time Large capacity motors; motor movements streamlined • Sheath flow automatically stops after 30 minutes of inactivity • Cover plate to protect reagent ports from incidental contamination • Sample trays redesigned – lighter, ergonomic, support cap-less syringes • Re-designed vial de-capper • Optical sensor eliminated The Micro PRO™ Software upgrades • Windows®-based, user-friendly interface • Main page re-design • Instant color-coded pass-fail results • View sample and tray status • • • • View/download results during sample analysis Reagent level alarm Context-sensitive Help files 21 CFR part 11 compliant Micro PRO™ Qualitative Analysis Product Screening Traditional methods USP <61> Bacteria 1:10 dilution of product 1ml in each of two Petri dishes with Soybean Casein Digest medium melted <45 C Incubate 48 to 72 hours at 30° C Count If zero counts, results are expressed as less than 10 cfu/ml Yeast and Mold 1:10 dilution of product 1 ml in each of two Petri dishes Saboraud Dextrose Agar Incubate 5 to 7 days at 20-25° C If zero counts, results are expressed as less than 10 cfu/ml Count Micro PRO™ Product Screening Protocol 1) Dilute 10g product in 90mL phosphate buffer or media (1:10 product suspension) 2) Mix to achieve a homogeneous solution 3) Add 1mL of the 1:10 product suspension to Tube A (Media Kit) 4) Incubate the samples at 30OC for 24-48 hours at ~200 rpm 5) After enrichment, prepare samples as directed in the Micro PRO™ Media Kit 6) Load samples on the Micro PRO™ for analysis 7) Pass/Fail results in 3 minutes/sample Micro PRO™ Media Kit Microbes 35µm filter Transfer swab from Tube A to B Tube A - GEM Add product, enrich Tube B - PB Add swab, mix Micro PRO™ Tube C - PB Add 0.1mL from Tube B Micro PRO™ Reagent Kit Micro PRO™ Pass/Fail Result Test Sample w/ Microbes All Microbes Stained Viable Microbes Stained Ideal for detecting microorganisms post-enrichment in: Finished Products Raw Materials In-Process Samples Interpretation of results • Micro PRO™ picture shows few to no counts within the analysis box (product baseline) • “Pass” result indicates that the sample does not contain microbial contamination Mold Area 1 counts/mL Bacteria Area 2 counts/mL Yeast Area 3 counts/mL Result 1 Result 2 Result 3 Overall Result 32 241 43 Pass Pass Pass Pass Interpretation of results • Micro PRO™ picture shows many counts within the analysis box (>4X baseline) • “Fail” result indicates that the sample contains microbial contamination Mold Area 1 counts/mL Bacteria Area 2 counts/mL Yeast Area 3 counts/mL Result 1 Result 2 Result 3 Overall Result 2628 1066 54 Fail Ambiguous Pass Fail Negative Control Positive A. niger Negative Control Positive P. aeruginosa Negative Control Positive C. albicans Micro PRO™ Product Screening Results Example of Signal:Noise ratios in various finished products Average Signal:Noise Sample S. aureus C. albicans A. niger Household cleaner 11779 241 384 Shave Gel 70369 686.5 16 Dish Soap 31172 1580 56.5 Mouthwash 6199 592 41.5 >50000 1150.5 25 1869 4933 8.5 Toothpaste >50000 13 41 Body wash 1280.5 10569 88 Hand Soap 269 400 23.5 Laundry detergent Fabric freshener Micro PRO™ Product Screening Results Household Cleaner – 24hr Neg Ctrl Box cnts/mL: 0/87/0 S. aureus spike S:N 11779 C. albicans spike S:N 439 A. niger spike S:N 406 Hand soap – 24hr Neg Ctrl Box cnts/mL: 21/549/21 S. aureus spike S:N 268.8 C. albicans spike A. niger spike S:N 399.6 S:N 23.5 Examples of Products Tested Bacteria-Yeast-Mold detection in 1 assay Personal Care Products OTC Pharma Products Hand soap Shave Gel Antacid Tablets Body wash Shampoo Liquid Antacid Face Scrub Conditioner Anti-itch cream Toothpaste Lotion Cold Syrup Mouthwash Multi-vitamin (chewable) Multi-vitamin (adult) Household Products Nose Drops Dish soap Stomach Relief Laundry detergent Fabric Freshener All-purpose household cleaner Product Testing Results Bacteria Yeast Negative Control Mold Micro PRO™ Agar Plate Micro PRO™ Agar Plate Micro PRO™ Agar Plate Micro PRO™ Agar Plate Dish Soap + + + + + + - - Toothpaste + + + + + + - - Shave Gel + + + + + + - - Multivitamin + + + + + + - - Results from Micro PRO™ are equivalent to the plate method. Micro PRO™ Quantitative Analysis Total Viable Organisms (TVO) Labeling Kit Viable Count/mL Test Sample w/ Microbes All Microbes Stained Ideal for enumerating viable microorganisms in: Process/Purified Water Surface Swabs Pure cultures Viable Microbes Stained Purified Water Monitoring •Results in less then 4 minutes •Quantitative output in counts/mL •Significant savings in technician labor Implementation Procedure 1) Determine the background range of the Micro PRO™ and TVO kit for accurate enumeration of TVO in purified water. 2) Define the method for purified water samples. Defining the analysis box. 3) Demonstrate that the Micro PRO™ results correlate well with the traditional plate methods. 4) Provides a laboratory with the necessary equipment to detect increases in purified water TVO counts within minutes of sample collection, enabling the scientist to respond proactively. Determining Background Limits 1) Collect purified water sample 2) 0.2mm filter sterilize 3) Background/negative control samples are analyzed on the Micro PRO™ using the Water Method 4) Background is typically less than 26 counts/ml Defining the Analysis Box 1) Microbes used: a. Escherichia coli, ATCC 25922 b. Pseudomonas aeruginosa, ATCC 9027 c. Staphylococcus aureus, ATCC 6538 d. Serratia marcescens, ATCC 13880 e. Ralstonia pickettii, ATCC 49129 f. A 6-isolate mix from in-house water system (unknown species) 2) Grow pure cultures and serially dilute in 0.2mm-filtered purified water 3) Analyze on the Micro PRO™ with the TVO kit 4) Set analysis box parameters in Water Method so the box encompasses all microbial populations 5) Use this standard analysis box in the Water Method for all negative control and test samples Results – Defining the Analysis Box Micro PRO™ Intensity Plots E. coli Ps. aeruginosa Staph. aureus Serratia marcescens After the box parameters were set using ATCC strains, a mix of isolates from Faucet A and Faucet B were analyzed on the Micro PRO™ to verify the placement of the analysis box R. pickettii Faucet Isolate Mix Purified Water Monitoring Protocol 1) Sanitize each sampling point if necessary. 2) Flush each sampling point for one minute. 3) Collect a minimum of 10mL per sampling point. 4) Dispense 2 x 3mL aliquots per sampling point into 5mL sample tubes. 5) Prepare 0.2-micron filtered water sample 6) Load tray and analyze using “Water Analysis” Tray Setup in the Micro PRO™ software Clean Water TVO: Ps. aeruginosa Spike Filtered DI H2O Box = 2 counts/0.25mL ~101 cfu/mL ~102 cfu/mL Box = 17 counts/0.25mL Box = 106 counts/0.25mL ~103 cfu/mL Box = 1241 counts/0.25mL ~104 cfu/mL Box = 16,069 counts/0.25mL Sample Micro PRO™ Counts/mL* Plate Counts/mL Micro PRO™ log10 Counts/mL Plate Counts log10 cfu/mL Filtered DI H2O (Bkgd) -- 0 -- -- ~101 Ps. aeruginosa 63 68 1.80 1.83 ~102 Ps. aeruginosa 455 593 2.66 2.77 ~103 Ps. aeruginosa 5,449 5,875 3.74 3.77 ~104 Ps. aeruginosa 70,692 58,750 4.85 4.77 *Micro PRO™ counts/mL are background corrected Purified Water Monitoring TVO & R2A Plate Counts Micro PRO R2A Plates 5-day R2A Plates 10-day Action Limit 100 90 80 Counts/mL 70 60 Alert Limit 50 40 30 20 10 0 1 2 3 4 5 6 7 8 9 10 Sample Number 11 12 13 14 15 16 17 Customer Studies Purified Water System counts/mL (CFU/mL) MQ system CPL2 Micro qual 2.50 2.00 1.50 1.00 0.50 0.00 MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ MQ 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 RBD Plate From: Hasher-Homesley, P.1, 2006. R&D Applications for the RBD3000. 1Johnson & Johnson Vision Care. Rapid Microbial Methods User’s Meeting, Chicago, IL Ecoli diluted in SPW RBD 3000 Counts vs. Standard Plate Counts over 10 Samples--Reproducibility RBD 3000 (counts/mL) 5.00 Plate Counts (cfu/mL) 4.50 4.00 3.50 Log10 Value 3.00 2.50 2.00 4.11 4.05 4.10 4.06 4.12 4.03 4.09 4.00 4.11 4.03 4.11 4.06 4.13 4.04 4.09 3.97 4.10 4.06 4.10 4.02 1 2 3 4 5 6 7 8 9 10 1.50 1.00 0.50 0.00 Sample Surface Swab Analysis/ Environmental Monitoring Environmental Sample Testing • Surface swabs are analyzed on the Micro PRO™ with results within 4 minutes • Data generated by the Micro PRO™ not only provides information about microbial populations but also indicates levels of residual product Microorganism Recovery • Recovery was demonstrated by testing pure cultures of Pseudomonas aeruginosa, Staphylococcus aureus, and Candida albicans • 100μL of the pure culture was pipetted onto a sterile Petri dish • A dry swab was used to absorb the sample • Additionally, 100μL of the final solution was spread plated onto Tryptic Soy Agar Microorganism Recovery Sample Micro PRO™ counts Plate Counts/mL Micro PRO™ log10/mL Plate log10/mL Log10 Difference Swab Control 17 NA NA NA NA P. aeruginosa 7004 7700 3.85 3.89 0.04 S. aureus 1327 1420 3.12 3.15 0.03 C. albicans 1782 3280 3.25 3.52 0.26 Environmental Swab Protocol • • • • • • Place a swab sample in a 5mL snap-cap tube containing 1mL filtered, sterile PB Break the swab handle over the rim of the tube Replace snap-cap and vortex swab and buffer for 30 seconds Press the swab against the side of the tube to express extra liquid Bring the volume to 3mL with filtered, sterile PB Analyze samples and controls on the Micro PRO™ 1 2 3 4 Environmental Sample Testing • Swab samples are directly analyzed on the Micro PRO™ • Result is obtained in minutes rather than overnight Negative Control Swab E.coli Spiked Swab Environmental Swab Box counts/0.25mL: 2 Box counts/0.25mL: 1,195 Indicative of residual product Microbial population within a predefined box Residual product; an additional box may be created to capture this data Pure Culture Enumeration Enumeration of Fermentation/Pure Cultures • Collect sample; if necessary dilute to <106 cfu/mL in PB • Dispense 3mL sample into 5mL snap-cap tube • Load sample into Micro PRO™ Sample Tray with capped syringe • Select pre-defined (or create new) Analysis/Tray Sequence • Micro PRO™ count result in 4 minutes Fermentation Applications Upstream 1. Media Contamination 2. Starter Culture Viability and/or Titer Downstream 1. Number of cells post inactivation 2. Number of cells after processing 3. Cell Concentrations Fermentation 1. Process Monitoring 2. Biomass and/or Viable cell enumerations 3. Determination of when to harvest or induce Spores + Vegetative Vegetative Spores Bacillus atrophaeus Spores vs. Vegetative TVO – Candida albicans in PB PB Background Box = 1 count/0.25mL ~101 cfu/mL ~102 cfu/mL ~103 cfu/mL ~104 cfu/mL Box = 2 counts/0.25mL Box = 33 counts/0.25mL Box = 216 counts/0.25mL Box = 2,027 counts/0.25mL Sample Micro PRO™ Counts/mL* Plate Counts/mL Micro PRO™ log10 Counts/mL Plate Counts log10 cfu/mL PB Background -- 0 -- -- ~101 C. albicans in PB 8 12 0.90 1.08 ~102 C. albicans in PB 140 128 2.15 2.11 ~103 C. albicans in PB 921 1,175 2.96 3.07 ~104 C. albicans in PB 8,648 12,500 3.94 4.10 *Micro PRO™ counts/mL are background corrected Correlation of Micro PRO™ TVO Counts vs. Plate Counts E. coli 8739 E. coli 25922 S. aureus 6538 Ps. aeruginosa 9027 Micro PRO Counts (log10/mL) 7.0 6.0 5.0 4.0 3.0 2.0 1.0 0.0 0.0 1.0 2.0 3.0 4.0 5.0 Plate Counts (log 10/mL) Escherichia coli 8739 (R2 = 0.9916), Escherichia coli 25922 (R2 = 0.9992), Staphylococcus aureus 6538 (R2 = 0.9988) and Pseudomonas aeruginosa 9027 (R2 = 0.9984). 6.0 7.0 Correlation of Micro PRO™ TVO Counts vs. Plate Counts A. niger spores 16404 C. albicans 10231 Micro PRO Counts (log 10/mL) 6.0 5.0 4.0 3.0 2.0 1.0 0.0 0.0 1.0 2.0 3.0 4.0 Plate Count (log 10/mL) Aspegillus niger spores 16404 (R2 = 0.9959) and Candida albicans 10231 (R2 = 0.9971) 5.0 6.0 Microorganisms Enumerated with AATI Technology • • • • • • • • • • • • • • • • • • • • • • • Aeromonas caviae Aeromonas hydrophila Aspergillus niger spores Bacillus atrophaeus Bacillus atrophaeus spores Bacillus pumilus Bacillus pumilus spores Bacillus subtilis Bacillus subtilis spores Bordetella bronchisceptica Brachyspira (Serpulina) hyodysenteriae Burkholderia cepacia Campylobacter jejuni Candida albicans Candida glabrata Citrobacter freundii Clostridium perfringens Cryptococcus spp. Cryptosporidium parvum oocysts Enterobacter aerogenes Enterobacter cloacae Enterococcus casseliflavus Enterococcus durans • • • • • • • • • • • • • • • • • • • • • • Enterococcus faecium Enterococcus faecalis Enterococcus gallinarum Enterococcus hirae Enterococcus mundtii Erysipelothrix rhusiopathiae Escherichia coli Escherichia coli O157:H7 Escherichia coli O25:HN Escherichia coli O15:NM Escherichia coli O1:NM Escherichia coli O7:NM Escherichia coli O78:NM Escherichia coli ON:H8 Escherichia coli ON:NM Escherichia coli O8:HN Geobacillus stearothermophilus Geobacillus stearothermophilus spores Giardia lamblia cysts Haemophilus parasuis Haemophilus somnus Halobacterium salinarum • • • • • • • • • • • • • • • • • • Klebsiella pneumoniae Lactobacillus acidophilus Lactobacillus casei Lactobacillus delbrueckii Lactobacillus lindneri Lactobacillus plantarum Lactococcus lactis Lawsonia intracellularis Leptospira pomona Listeria grayi Listeria innocua Listeria ivanovii Listeria monocytogenes Listeria seeligeri Listeria welshimeri Micrococcus candicans Micrococcus luteus Moraxella bovis Microorganisms Enumerated with AATI Technology • • • • • • • • • • • • • • • • • • • • • • • Mycoplasma bovis Mycoplasma hyopneumoniae Nannocystis exedens Oxalobacter formigenes Pantoea agglomerans Pasteurella multocida Pediococcus acidilactici Pediococcus damnosus Proteus mirabilis Pseudomonas aeruginosa Pseudomonas fluorescens Pseudomonas putida Ralstonia pickettii Raoutella terrigena Saccharomyces cerevisiae Salmonella adelaide Salmonella anatum Salmonella choleraesuis Salmonella dublin Salmonella enteriditis Salmonella hadar Salmonella heidelberg Salmonella iverness • • • • • • • • • • • • Salmonella schalwijk Salmonella typhimurium Salmonella worthington Serratia marcescens Shigella boydii Staphylococcus aureus Staphylococcus epidermidis Staphylococcus saprophyticus Stenotrophomonas maltophila Streptococcus bovis Streptococcus equinus Streptococcus pyogenes Installation, Training, Validation & Support for the Micro PRO™ Pre-Installation • Feasibility is demonstrated by providing information on similar applications or performing a feasibility study • Potential clients can contact current users of the Micro PRO™ technology • Potential clients are welcome to visit the Ames, IA facility for a hands-on demonstration Training • Training for up to two employees at the Ames, IA facility is included in the purchase of the Micro PRO™ system Installation • Advanced Analytical issues an Installation Checklist to ensure the client’s lab is equipped with the materials and environment necessary to operate the Micro PRO™ • Micro PRO™ is installed by Advanced Analytical personnel using Installation and Operation Qualification (IQ/OQ) documents Installation, Training, Validation & Support for the Micro PRO™ Validation • Advanced Analytical provides a validation guide and protocols for several applications to assist in the implementation process • Provide onsite validation support and testing • Conduct customer validation testing at our Ames, IA facility On-going Support • Comprehensive support in the US is provided by Advanced Analytical’s team of microbiologists and service technicians • International equipment and application support is provided by Advanced Analytical and our extensive network of distributors • Preventive maintenance program • 21 CFR Part 11 compliant software The Micro PRO™ Delivers on the Promise of Rapid Microbiology • Versatile system covering the many aspects of microbial testing (qualitative and quantitative modes of operation) • Automated, high throughput processing (up to 20 samples/hour) with unattended analysis • Reagents stable at room temperature for 7 days • Easy to use and maintain Media kit containing all necessary components Intuitive, 21 CFR compliant software Preventive maintenance agreements available • Excellent technical and validation support THANK YOU www.aati-us.com RBD3000 Customer Case Studies VISTAKON (J&J) Efficacy studies - Flow Diagram of current methodology vs. use of RBD 3000 subculture organism 24 hours set up testing 24-48 hours incubation conduct testing plate samples, 48 hour incubation incubate use of AATI RBD 3000 From conducting test to data output for 24 samples = 6 incubate read plates Data crunch crunch data From conducting test to data output for 24 samples = 58 hours From: Hasher-Homesley, P.1, 2004. Validation of the RBD3000 Flow Cytometer for Bacterial Enumeration. 1Johnson & Johnson Vision Care. Rapid Microbial Methods Conference, San Diego, CA hours QC PA ATCC 9027 RBD 3000 counts/ml (log) RBD 3000 ID 1508 vs. Pour Plate 7.00 6.00 R2 = 0.9903 5.00 4.00 3.00 2.00 1.00 0.00 0.00 1.00 2.00 3.00 4.00 5.00 6.00 Pour Plate CFU/ml (log) From: Hasher-Homesley, P.1, 2004. Validation of the RBD3000 Flow Cytometer for Bacterial Enumeration. 1Johnson & Johnson Vision Care. Rapid Microbial Methods Conference, San Diego, CA. 7.00 cfu/ml: counts/ml RBD 3000 PQ RUN 1: method equivalency 8 6 4 2 0 1 2 3 4 5 6 7 8 9 10 11 12 13 samples Plate Count RBD 3000 From: Hasher-Homesley, P.1, 2004. Validation of the RBD3000 Flow Cytometer for Bacterial Enumeration. 1Johnson & Johnson Vision Care. Rapid Microbial Methods Conference, San Diego, CA. 14 Equipment equivalency ID 1508 vs 1506 RBD 3000 # 1508 VS. 1506 R2 = 0.9914 RBD 3000 # 1508 6.00 5.00 4.00 3.00 2.00 1.00 0.00 0.00 1.00 2.00 3.00 4.00 5.00 RBD 3000 # 1506 From: Hasher-Homesley, P.1, 2004. Validation of the RBD3000 Flow Cytometer for Bacterial Enumeration. 1Johnson & Johnson Vision Care. Rapid Microbial Methods Conference, San Diego, CA. 6.00 Annual Cost for Efficacy studies Current method vs. RBD 3000 system • Current method Estimated annual expenditure for Efficacy studies • RBD 3000 Estimated 1st year expenditure for Efficacy studies using the RBD 3000 system $219,960 $126,640 Estimated 1st year savings of $93,320 After 1 year warranty maintenance contract $9600 Estimated thereafter savings of $172,320 Estimated annual expenditure for Efficacy studies $47,640 From: Hasher-Homesley, P.1, 2004. Validation of the RBD3000 Flow Cytometer for Bacterial Enumeration. 1Johnson & Johnson Vision Care. Rapid Microbial Methods Conference, San Diego, CA. Applications • BI Enumerations • In-Process and End-Use solution testing • Label claim enumerations from outside vendor sources i.e. quanti-cults® and spore preparations • Routine finished goods Bioburden Testing • Microbial adhesion assays • Sample purity check From: Hasher-Homesley, P.1, 2004. Validation of the RBD3000 Flow Cytometer for Bacterial Enumeration. 1Johnson & Johnson Vision Care. Rapid Microbial Methods Conference, San Diego, CA. Advantages of RBD 3000 Rapid bacteria detection • Counting organisms in real time within a defined volume Total bacterial testing or specific pathogen testing • Non-specific labeling with fluorescent probes • Organism specific labeling with selective fluorescent antibodies or gene probes Automated sample preparation and testing • Real time validation • 42-position auto sampler for high sample throughput Fast, accurate and easy to use • Accurate detection 101-106 cfu/ml and reproducibility shown at 2-3 x 101 • Detection 0.1 micron and larger • Red laser excitation for reduction in background signal of non-bacterial origin Standardized testing protocols • In house method development in the form of application notes providing customers with working protocols On system reagents for unattended operation • Reducing chances of cross contamination and human error 21 CFR Part 11 Compliant From: Hasher-Homesley, P.1, 2004. Validation of the RBD3000 Flow Cytometer for Bacterial Enumeration. 1Johnson & Johnson Vision Care. Rapid Microbial Methods Conference, San Diego, CA. Personal Care Products Company Evaluation performed : - Presence/Absence of bacteria in the final product - Bacterial water testing - Environmental surface monitoring on the production line Presence/Absence 1. Dilute 1mL product in 9mL Enrichment Broth 2. Place samples at 32oC and rock for 18-24 hours 3. Dilute enriched samples 10-3 in 10mM PB, 40µm filter if necessary 4. Dispense 3mL sample into a 5mL snap cap tube 5. Analyze on the RBD 3000 for TVO Interpretation of Results: Enriched samples are considered positive if they are 10x the background Results RBD 3000 Results Plate Results Sample #1 + + Sample #2 - - Sample #3 + + Sample #4 - - Sample #5 - - Sample #6 - - Sample #7 - - Sample #8 - - Sample #9 - - Sample #10 - - Sample #11 + + Sample Approximately 300 samples were run parallel to standard cultural methods. Results from RBD are equivalent to the plate method. Bacterial water testing - 5 minutes per water sample for microbial results. - Samples can be analyzed directly on the RBD with enumeration of viable cells per mL. - Microbial situations can be evaluated and the source determined in minutes. (i.e. city water main break) Environmental surface monitoring on the production line RBD 3000 detected surface contamination of bacteria and residual product. RBD 3000 will help validate cleaning procedures and ensure all residual product is removed before beginning new batch. Negative control Microbial population Product residue Conclusions • Capable of detecting bacterial contamination using Presence/Absence test in finished goods • Capable to enumerate bacterial contamination in DI water. Results were obtained within hours after pulling samples • Environmental surface monitoring tests on the RBD 3000 detected microbial contaminants. • Unexpected result showed residual product could also be seen after cleaning. • Pass/Fail criteria were able to be set in RBD 3000 to automatically tell user if samples are good/bad Procter & Gamble Loose Adsorbents study • As a screener, loose adsorbents are placed in water to test their effectiveness on bacterial removal • Enumerates the removal efficiency and potential capacity for microbial adsorption • Prior to counting, the sample is passed through a 5 μm syringe filter to remove adsorbent • Background run to ensure filtered adsorbents had no adverse effect on RBD • For correlation, the RBD counts were initially compared to other methods (Pour plating and ColilertTM) From: Kozak, K.1, Petersen, J. and Lasky,S.J.2, 2004. Rapid Microbiological Testing Using Flow Cytometry in Support of Product Development. 1Procter and Gamble and 2Advanced Analytical. European Microbiology Event of the Year (IVT), Amsterdam, The Netherlands. Typical Scatterplots of Adsorbent Study Control • Microbial removal over time • Quickly know if adsorbent is efficacious After 60 minutes After 120 minutes After 30 seconds From: Kozak, K.1, Petersen, J. and Lasky,S.J.2, 2004. Rapid Microbiological Testing Using Flow Cytometry in Support of Product Development. 1Procter and Gamble and 2Advanced Analytical. European Microbiology Event of the Year (IVT), Amsterdam, The Netherlands. E. Coli with Adsorbent 1.00E+07 Counts/mL 1.00E+06 1.00E+05 1.00E+04 1.00E+03 1.00E+02 RBD counts/mL 1.00E+01 Colilert cfu/mL 1.00E+00 0 10 20 30 40 50 Time (minutes) From: Kozak, K.1, Petersen, J. and Lasky,S.J.2, 2004. Rapid Microbiological Testing Using Flow Cytometry in Support of Product Development. 1Procter and Gamble and 2Advanced Analytical. European Microbiology Event of the Year (IVT), Amsterdam, The Netherlands. 60 Counts/mL R. terrigena with Adsorbent 1.00E+07 1.00E+06 1.00E+05 1.00E+04 1.00E+03 1.00E+02 1.00E+01 1.00E+00 RBD counts/mL Colilert cfu/mL 0 10 20 30 40 50 60 Time (minutes) From: Kozak, K.1, Petersen, J. and Lasky,S.J.2, 2004. Rapid Microbiological Testing Using Flow Cytometry in Support of Product Development. 1Procter and Gamble and 2Advanced Analytical. European Microbiology Event of the Year (IVT), Amsterdam, The Netherlands. Counts/mL P. aeruginosa with Adsorbent 1.00E+07 1.00E+06 1.00E+05 1.00E+04 1.00E+03 1.00E+02 1.00E+01 1.00E+00 RBD counts/mL Plates cfu/mL 0 10 20 30 40 50 Time (minutes) From: Kozak, K.1, Petersen, J. and Lasky,S.J.2, 2004. Rapid Microbiological Testing Using Flow Cytometry in Support of Product Development. 1Procter and Gamble and 2Advanced Analytical. European Microbiology Event of the Year (IVT), Amsterdam, The Netherlands. 60 Loose Adsorbent Screening • How is this useful to R&D? • Good correlation between traditional methods and the RBD 3000 • Rapid screener for potential adsorbents • Pretreatment (5um filter) allows for bacterial enumeration in a complex media • Noticed differences in adsorption of microbes From: Kozak, K.1, Petersen, J. and Lasky,S.J.2, 2004. Rapid Microbiological Testing Using Flow Cytometry in Support of Product Development. 1Procter and Gamble and 2Advanced Analytical. European Microbiology Event of the Year (IVT), Amsterdam, The Netherlands. RBD 3000 Reference Miller, M. J., Encyclopedia of Rapid Microbiological Methods, Volume 2, DHI Publishing, River Grove, IL, USA. 2005. Chapter 16: Steger, A. M. “Rapid enumeration of microorganisms using Advanced Analytical’s RBD 3000.” Encyclopedia of Rapid Microbiological Methods, Volume 2. Ed. M. J. Miller. River Grove, IL, USA: DHI Publishing, LLC, 2005. (AATI) Chapter 17: Kozak, K. C. and D. E. Langworthy. “Rapid Microbial Counting by Flow Cytometry: Validation and Implementation for Research and Development (R&D) Applications.” Encyclopedia of Rapid Microbiological Methods, Volume 2. Ed. M. J. Miller. River Grove, IL, USA: DHI Publishing, LLC, 2005. (P&G) Chapter 18: Homesley, P. H. “The RBD 3000 Rapid Bacterial Enumeration System as an Alternative to Traditional Pour Plate Enumeration.” Encyclopedia of Rapid Microbiological Methods, Volume 2. Ed. M. J. Miller. River Grove, IL, USA: DHI Publishing, LLC, 2005. (J&J)