22.3.1 Vitek 2

The Vitek 2 instrument is a broth microdilution-based AST system (Figure 22.1), which uses 64-well plastic cards containing 17-20 antimicrobial agents (Figure 22.2). Combinations of primary Gram-negative susceptibility cards can be combined with extension susceptibility cards resulting in the testing of 18 or 19 additional antimicrobial agents on the same isolate. The Vitek 2 measures changes in turbidity over time (growth curve), comparing a growth control well with wells containing various drug concentrations. Results are reported in 4–18 h as MIC and S-I-R category, depending on the growth rate and susceptibility parameters of the organism. The Vitek 2 instrument replaced the prior less automated Vitek 1 (Vitek Legacy) instrument over the period 1999–2010. Two Vitek 2 instruments are available with test card (ID and AST) capacities of 60 cards (Vitek 2) and 120 cards (Vitek 2 XL) with an expanded capability to connect two Vitek 2 modules to the same computer. In addition, three Vitek 2 Compact instruments are available with test card capacities of 15, 30, and 60 cards. Table 22.1 lists a variety of susceptibility cards, which are available for Gram-negative and Gram-positive organisms.

The Vitek 2 system contains computer software to also deduce the susceptibility results for selected Gram-positive bacteria (Staphylococcus spp., Enterococcus spp., Streptococcus agalactiae) for an additional four to ten antimicrobial agents, resulting in the reporting of 23–30 antimicrobial agents per card (Table 22.1). The Vitek 2 system incorporates test setup and sample verification with a Smart Carrier component. All AST inoculum dilutions are performed by the instrument, as well as card sealing and incubator loading functions. Optical reading of cards is performed every 15 min in the Vitek 2, with a multichannel fluorometer and photometer to record fluorescence, turbidity, and colorimetric signals. Susceptibility results are reported in 4–18 h, depending on the organism and susceptibility parameters. The data management system of the Vitek 2 is a PC Windows-based platform termed PC/Observa (Table 22.1). The software is FDA-cleared and is configured by the manufacturer to FDA-defined MIC interpretive breakpoints, as are all automated AST systems. However, the Vitek software also gives the customer the option to configure MIC interpretive breakpoints according to the most recent CLSI AST performance standards [21]. The PC/Observa platform also provides a selection of quality control options, and has multi-instrument access capabilities. The detection of antimicrobial resistance is also facilitated in the Vitek 2 by the Advanced Expert System (AES). This software system validates MIC results by a set of in vitro testing rules based on 20,000 MIC distributions with over 2000 phenotypes, provides result interpretations and corrections, and adds footnotes (CLSI or laboratory defined) for communication to physicians. A biological correction is recommended by the Vitek 2 AES if it detects a single MIC inconsistency with the bacterial identification compared to the internal database. The Vitek 2 system for AST can be connected with the automated microbial identification system, Vitek MS, which uses mass spectrometry technology termed MALDI-ToF (matrix assisted laser desorption ionization time of flight) to provide culture isolate identification results in minutes. The AST and ID systems are connected via the laboratory informatics system, the Vitek Myla.

In an evaluation by Barry et al., MIC values from the Vitek 2 with AES was compared to a reference MIC agar dilution method against clinical isolates tested in five laboratories [4]. The essential agreement (MIC within one dilution of the reference method) for the Vitek 2 was 95.5% for 3074 Gram-negative rods, 96.7% for 1674 staphylococci, and 96.5% for 315 enterococci. In the same study, the Vitek 2 with AES appropriately detected a subset of characterized resistance mechanisms among the Gram-negative rods, staphylococci, and enterococci [4]. Blondel-Hill et al. evaluated the Vitek 2 with AES in comparison to a reference broth microdilution method against 300 Enterobacteriaceae and reported an overall correlation of susceptibility interpretations of 96.2% [8].

Performance characteristics for the Vitek 2 were compared with the Phoenix system (BD Diagnostics) in a study by Eigner et al. with an evaluation of 307 clinical isolates including Enterobacteriaceae, Gram-negative non-fermenters, Staphylococcus spp., and Enterococcus spp. [24]. The overall category agreement for both instruments was 97.0% compared to a reference broth microdilution method, and the minor error, major error (false positive), and very major error (false negative) rates for the Vitek 2 were 2.8, 0.2, and 1.7, respectively. The Vitek 2 with AES was evaluated for its ability to identify β-lactam phenotypes in a test panel of 196 isolates of Enterobacteriaceae and P. aeruginosa, and overall, the AES was able to ascertain the β-lactam phenotype for 93.4% of the isolates tested [62].

The Vitek 2 was evaluated along with five other commercial MIC systems for the accuracy of detecting vancomycin MICs with a range of ≤ 1–8 mg/mL among 129 Staphylococcus aureus isolates from the CDC strain collection [67]. The essential agreement (±1 dilution) for the Vitek 2 GP61 card (currently replaced by the GP75 card, Table 22.1) was 100% and the overall category agreement was 90.7% [67]. Junkins et al. evaluated the implementation of cefoxitin on the Vitek 2 GP66 card to enhance the detection of methicillin-resistant S. aureus (MRSA) in comparison to two reference methods: oxacillin MIC reference broth microdilution and mecA gene detection [42]. For the 448 MRSA and 172 methicillin-susceptible S. aureus tested, the categorical agreement for the Vitek 2 was 99.7%. In a study of susceptibility testing of enterococci, the Vitek 2 was evaluated with 150 clinical isolates of enterococci, which included vanA, vanB, and vanC strains and six species of enterococci [29]. The essential agreement results for ampicillin, vancomycin, teicoplanin, and high-level gentamicin resistance were 93, 95, 97, and 97%, respectively. Kobayashi et al. evaluated the Vitek 2 against 32 strains of vancomycin-resistant enterococci (VRE), which were characterized by PCR as 23 vanA and 9 vanB [45]. In addition to the PCR analysis the Vitek 2 results were compared with two CLSI reference methods, agar dilution and broth microdilution. Among the seven antimicrobial agents tested, the Vitek 2 exhibited one very major error for teicoplanin, no major errors to any of the antimicrobials tested, and seven minor errors for teicoplanin. Overall, 54% of MIC test results were completed by the Vitek 2 within 7 h and all MIC values were determined within 13 h of incubation [45]. The Vitek 2 is capable of performing susceptibility testing of Streptococcus pneumoniae with a configured MIC card (GP74, Table 22.1) containing enriched growth medium. In a report by Jorgensen et al., 53 challenge strains of pneumococci with known resistance mechanisms and 818 clinical isolates were studied with the Vitek 2 compared with CLSI reference broth microdilution method in three separate laboratories [37]. The overall agreement of the Vitek 2 MIC values with the 10 antimicrobial agents studied was 96.3% with a mean time of results generated of 8.1 h.

22.3.2 MicroScan WalkAwayplus System

The MicroScan WalkAway plus System (Figure 22.3) automated AST system is a broth microdilution method utilizing a standard 96-microwell panel (Figure 22.4). The WalkAway plus System is available in both 40- and 96-panel capacity models and was designed to replace the WalkAway-40 and the WalkAway 96 SI models. The instrument is capable of reading either conventional or rapid panels. The microwells contain serial dilutions of dehydrated antimicrobial agents. Three types of panel configurations for Gram-negative and three for Gram-positive bacteria are available: (i) Combo panels containing both antimicrobial dilutions and identification (ID) substrates; (ii) Breakpoint Combo panels containing antimicrobials in a breakpoint dilutions and ID substrates; and (iii) MIC panels containing only antimicrobial dilutions. Breakpoint panels contain only two or three concentrations of each antimicrobial agent, and the resulting MIC corresponds to the interpretive category S, I, or R. In contrast, standard MIC panels contain a wide range of doubling dilution antimicrobial concentrations for the determination of the MIC. The MicroScan panel types are listed in Table 22.1. The panels are manually inoculated and rehydrated by using the RENOK inoculator and then placed into the incubator-reader component of the WalkAway. Results are obtained after 15 to 18 h by turbidimetric readings of overnight conventional panels and after 4.5–18 h readings of rapid panels. Combination Gram-negative ID and AST panels called MicroScan Synergies plus Negative and rapid/S plus Negative panels were introduced in 2005, voluntarily recalled in 2013, and no longer available in the United States. The Synergies plus Negative 96-well panels were configured with 36 wells containing fluorogenic substrates for rapid organism identification (2.5 h) and 60 wells with antimicrobials in Mueller–Hinton broth for the turbidimetric determination of MICs utilizing a proprietary technique to optimize growth and allow readings from 4.5 to 18 h when needed. Since the rapid panels were no longer available at the time of writing this chapter, only the conventional panels are listed in Table 22.1. The WalkAway plus System includes the LabPro Information Manager system software for ID and AST data management. The optional LabPro Alert System software incorporates the detection of unusual resistance results and incorporates institution-specific infection prevention guidance into footnotes or comments for physician review. An expert software package was added in version 3 of the LabPro Alert_EX System [76].

An evaluation of the MicroScan WalkAway system was conducted by Rittenhouse et al., with results from a conventional MicroScan Gram-negative MIC panel compared to reference broth microdilution using 500 Gram-negative clinical isolates tested against nine antimicrobial agents [60]. Very major errors (false susceptibility) were detected at a rate of 3.0% (15 of 500), and no major errors (false resistance) were detected. Jorgensen et al. evaluated the MicroScan ESBL plus panel against 100 genetically characterized extended-spectrum β-lactamase (ESBL)-producing isolates consisting of 64 Enterobacteriaceae that produced CTX-M, 17 that produced SHV or TEM ESBL, and 19 that produced CTX-M and SHV ESBLs [40]. The MicroScan ESBL plus panel detected 98% of the isolates. A study by Bulik et al. compared MicroScan panels and reference broth microdilution in an evaluation of meropenem MICs from carbapenemase-producing Klebsiella pneumoniae with KPC genotypes [14]. A total of 46 K. pneumoniae isolates were tested, which were all modified Hodge test positive and bla_KPC positive. The MicroScan panels demonstrated a 95.6% essential agreement with the reference method, with 2.2% minor errors and no major or very major errors [14].

MicroScan Pos MIC conventional (overnight) panels were evaluated by Tenover et al. for the ability to detect linezolid susceptibility against a challenge panel of 50 enterococci and 50 staphylococci [69]. The challenge panel included 17 enterococci and 15 staphylococci that were nonsusceptible to linezolid. The MicroScan Pos MIC panels were read using the WalkAway with LabPro software and the category agreement with the CLSI broth microdilution reference method was 96.0%. In a study by Swenson et al., 129 S. aureus isolates were evaluated for the ability of the MicroScan Pos MIC 26 panel to detect vancomycin susceptible (n = 84) and vancomycin intermediate (n = 45) strains from the CDC collection [67]. The MicroScan Pos MIC 26 panel demonstrated an overall category agreement of 92.2% identifying all 45 of the VISA strains and categorizing 10 of the 84 vancomycin-susceptible strains as VISA. MicroScan has a specific panel for the susceptibility testing of Streptococcus pneumoniae called the MICroSTREP plus panel (Table 22.1). In a report by Mittman et al., 311 clinical isolates of S. pneumoniae were tested using the MICroSTREP plus panel compared to a reference broth microdilution method [52]. The overall categorical agreement of the MicroScan MIC values with the 13 antimicrobial agents studied was 99.5% and the categorical agreement for penicillin was 98.7%.

22.3.3 Phoenix System

The BD Phoenix Automated Microbiology System utilizes combination panels for bacterial ID and AST. The combination MIC/ID panels contain a total of 136 wells, of which 51 are utilized for ID and up to 85 are utilized for AST (Table 22.1). A bacterial inoculum for ID and a second inoculum for AST are poured into receptacles of the respective ID and AST sections of the single combination panel. The panels are tilted and each dehydrated well is then self-inoculated. Susceptibility results are determined in the Phoenix system by utilizing a resazurin-based redox dye as well as kinetic measurements of turbidity to detect bacterial growth in the presence of an antimicrobial agent. Up to 100 panels can be placed into the Phoenix system for ID, AST, or combination of ID and AST. The panels are automatically incubated for up to 18 h, and the results are read and reported. The addition of a new Gram-negative susceptibility panel in 2014 called the Emerge NMIC-140 (Table 22.1) was designed for MIC susceptibility testing on the Phoenix system to be used in combination with the BD Bruker MALDI-ToF Biotyper system for the rapid identification of culture isolates using mass spectrometry. The two systems are connected through the BD EpiCenter software system for data management. The Phoenix system is shown in Figure 22.5, and the Phoenix Combo ID/AST panels are show in Figure 22.6.

An evaluation of the Phoenix system was performed by Eigner et al. with an evaluation of 307 clinical isolates including 141 Enterobacteriaceae, 22 Gram-negative non-fermenters, 93 Staphylococcus spp., and 51 Enterococcus spp. [24]. The category agreement for the Phoenix system compared to a reference MIC broth microdilution method was 96.5% for Enterobacteriaceae, 84.8% for Gram-negative non-fermenters, 98.9% for Staphylococcus spp., and 98.0% for Enterococcus spp. The overall category agreement was 97.0% with 3.0% minor errors, 0.3% major errors (false positives), and 0.6% very major errors (false negatives). The evaluation was performed using NMIC/ID 14 panels for Gram-negative rods and PMIC/ID 13 panels for Gram-positive cocci, which have since been replaced and updated on the BD Phoenix system (Table 22.1).

Junkins et al. evaluated the implementation of cefoxitin on the Phoenix PMIC/ID-102 panel to determine if the detection of methicillin-resistant S. aureus (MRSA) was enhanced in comparison to two reference methods: oxacillin MIC reference broth microdilution and mecA gene detection [42]. For the 448 MRSA and 172 methicillin-susceptible S. aureus tested, the categorical agreement for the Phoenix was 99.8%. The Phoenix PMIC/ID-100 panel was evaluated by Tenover et al. for the ability to detect linezolid susceptibility against a challenge panel of 50 enterococci and 50 staphylococci [69]. The challenge panel included 17 enterococci and 15 staphylococci that were nonsusceptible to linezolid. The overall categorical agreement for the Phoenix panel compared to the CLSI broth microdilution reference method was 89.6% and the essential agreement (+/– one MIC doubling dilution) was 95.8%. Buchan et al. evaluated the ability of the Phoenix system to detect inducible resistance to clindamycin among 524 clinical isolates of Staphylococcus spp. [11]. Compared to a double-disk diffusion reference method to detect inducible clindamycin resistance, the Phoenix showed a sensitivity of 100% and specificity of 99.6%.

Richter et al. conducted a multicenter evaluation of the Phoenix system for susceptibility testing of 13 agents against 2,013 streptococcal isolates, including 938 S. pneumoniae, 396 group B streptococci, 369 viridans group streptococci, 290 β-hemolytic Streptococcus groups A, C, and G, and 20 other streptococci [59]. In comparison to a broth microdilution reference method, the categorical agreement of the Phoenix panels ranged from 92 to 100% with one exception for viridians streptococci and penicillin, which was 87%. Mittman et al. evaluated 311 clinical isolates of S. pneumoniae using the Phoenix SMIC/ID-100 panel compared to a reference broth microdilution method [52]. The overall categorical agreement of the Phoenix panel with the 13 antimicrobial agents studied was 99.3% and the categorical agreement for penicillin was 95.5%.

22.3.4 Sensititre ARIS 2X

Sensititre ARIS (Automated Reading and Incubation System) 2X is an automated, bench-top incubation and reading instrument that accommodates up to 64 Sensititre 96-microwell panels for broth microdilution antimicrobial susceptibility testing and/or organism identification. Sensititre antimicrobial susceptibility testing panels for diagnostic use contain serial dilutions of dehydrated antimicrobial agents and are intended to provide a MIC (μg/mL) and MIC interpretation (susceptible, intermediate, resistant). Panel configurations are available for Gram-positive and Gram-negative bacteria and are listed in Table 22.1; some antimicrobial agents are only tested at MIC breakpoint concentrations. In addition to the commercial panels listed in Table 22.1, Thermo Scientific (previously distributed by Trek Diagnostics Systems) can manufacture custom MIC panels (dehydrated or frozen) for investigators performing surveillance studies and evaluations of new antimicrobials. Sensititre panel inoculation may be automated, using the Sensititre AIM (Automated Inoculation Delivery System), or performed manually using a Sensititre Electronic Pipette. The inoculated panels are then loaded manually into the Sensititre ARIS 2X. Antimicrobial susceptibility testing panels for diagnostic use employ a proprietary substrate (non-fluorescent) in the media used to suspend the bacterial isolate and perform panel inoculation. Hydrolysis of the substrate by bacterial enzymes releases fluorescence which is used to monitor growth in each well and determine MIC endpoints; a computer algorithm converts the fluorescent signal to a MIC. The Sensititre ARIS 2X uses an internal bar code scanner to identify each panel type, then it assigns an appropriate incubation time, and when this assigned time has elapsed (16 to 24 h), the system transports the panel to the OptiRead Automated Fluorometric Plate Reading System within the ARIS 2X with no manual intervention. The Sensititre Windows (SWIN) software system offers automated expert analysis, semi-automated analysis, or manual options on a single software platform. The current Sensititre ARIS 2X instrument was released in 2004 and is shown in Figure 22.7 and the Sensititre panels are shown in Figure 22.8.