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Etest

The Etest, also known as the Epsilometer test, is a quantitative microbiological method designed to determine the () of antibiotics and antifungals against bacterial and fungal isolates. It utilizes a plastic strip impregnated with a predefined gradient of the agent, spanning typically 15 twofold dilutions from 0.002 to 32 μg/mL, which is applied to an uniformly inoculated with the test . Following incubation, an elliptical zone of inhibition forms around the strip, and the is determined as the lowest concentration at which is inhibited, marked by the intersection of the ellipse's edge with the strip's scale. Developed in the late and introduced commercially in the early by (formerly AB Biodisk), the Etest represents an innovative blend of agar diffusion and dilution techniques, providing a cost-effective alternative to traditional methods for susceptibility testing (). The procedure involves preparing a standardized inoculum (equivalent to a 0.5 McFarland standard), swabbing it onto a suitable medium such as Mueller-Hinton , placing the perpendicular to any potential growth streaks, and incubating at 35–37°C for 18–24 hours (or longer for fastidious organisms). Results are interpreted according to guidelines from bodies like the Clinical and Laboratory Standards Institute (CLSI), categorizing isolates as susceptible, intermediate, or resistant based on the value, which aids in guiding targeted therapy. The Etest is widely applied in clinical laboratories for diagnosing infections such as , , and those in immunocompromised patients or chronic conditions like , where detecting emerging resistance patterns is critical. It supports over 90 agents, including combinations like ceftolozane/tazobactam, and complements automated systems like VITEK 2 for integrated and testing. Advantages include its simplicity, requiring minimal training and equipment, high reproducibility (with agreement rates of 90% or more within ±1–2 dilutions compared to reference methods), and utility in detecting subtle resistance phenotypes like heteroresistant vancomycin-intermediate (hVISA). However, limitations exist, such as potential interpretive errors (up to 30% for certain phenotypes like extended-spectrum production), inapplicability to some organisms like , and higher costs for high-volume testing compared to disk diffusion. Overall, the Etest remains a of AST, contributing to efforts amid rising global resistance, with over 2.8 million antibiotic-resistant infections reported annually in the alone.

Overview

Definition and Purpose

The Etest is a proprietary, gradient-based susceptibility testing method developed by for quantitatively determining the () of antibiotics or antifungals against various microorganisms. This technique employs a plastic strip with a predefined, stable of concentrations to generate precise values, expressed in μg/mL, typically spanning 15 two-fold dilutions such as from 0.002 to 32 μg/mL, depending on the specific strip and agent. The primary purpose of the Etest is to identify the lowest concentration of an agent that inhibits visible growth of a target bacterium or , thereby providing essential quantitative data to inform personalized decisions in infectious diseases. By delivering exact results alongside interpretive categories, it supports efforts, aids in managing critical infections like or , and helps detect emerging resistance patterns. This is particularly valuable in clinical settings where precise dosing is needed to optimize therapy outcomes while minimizing resistance risks. The Etest is applicable to a broad scope of microorganisms, including such as Staphylococcus aureus and Enterococcus species, like Pseudomonas aeruginosa and Enterobacterales, fastidious organisms including Haemophilus influenzae and Streptococcus pneumoniae, as well as certain fungi such as Candida species using antifungal strips. It accommodates both non-fastidious and fastidious aerobes, anaerobes, and slow-growing pathogens, making it versatile for routine and specialized susceptibility testing across over 90 antimicrobial agents.

Principle of Operation

The Etest, also known as the epsilometer test, operates on the principle of combining dilution and methodologies to quantify the (MIC) of an agent against a bacterial isolate. The core component is a thin, inert, non-porous strip precoated with a predefined gradient of the antimicrobial on one side and a corresponding MIC scale (in μg/mL) on the opposite side. This gradient typically spans several log2 dilutions, such as from 0.016 to 256 μg/mL for many agents, ensuring a continuous range of concentrations. When the strip is applied to an surface inoculated with the test , the antimicrobial diffuses from the strip into the agar underneath it, establishing a stable concentration that decreases exponentially from the strip's surface. The diffuses from the strip into the underneath it, establishing a stable, concentration gradient that correlates directly with values. This process occurs passively during , typically at 35–37°C for 16–20 hours, allowing the antimicrobial to diffuse radially while the bacterial inoculum grows. The nature of the gradient ensures that the concentration at any point along the strip's length matches the MIC scale, providing a stable and symmetric front that minimizes variability from factors like depth or time. This mechanism enables precise determination of the lowest concentration inhibiting visible , distinguishing Etest from qualitative disk methods. Following , inhibition manifests as a symmetric elliptical zone centered along the , with the ellipse's edges demarcating the transition from to no . The is read at the point where the ellipse's pointed end intersects the strip's scale, representing the concentration at which is completely inhibited. This intersection provides a quantitative , with the elliptical shape arising from the isotropic in the plane perpendicular to the . The method's design ensures that the inhibition zone's symmetry facilitates accurate reading, typically to the nearest log2 dilution. Etest results are standardized to align with Clinical and Laboratory Standards Institute (CLSI) and European Committee on Antimicrobial Susceptibility Testing (EUCAST) guidelines for interpretation, achieving essential agreement rates of ≥90% with reference dilution methods across laboratories. This reproducibility stems from the predefined and controlled , validated through multicenter studies demonstrating consistency for over 90 antimicrobial agents against various pathogens. Adherence to these guidelines ensures that values can be categorized as susceptible, , or resistant using established breakpoints.

Procedure

Inoculum Preparation and Inoculation

The inoculum preparation for the Etest involves selecting 3-5 well-isolated colonies from a pure culture on a non-selective agar plate, ideally no more than 18-24 hours old, to ensure active growth and genetic homogeneity. These colonies are emulsified in sterile saline (0.85% NaCl) or Mueller-Hinton broth to create a uniform suspension adjusted to a turbidity of 0.5 McFarland standard, equivalent to approximately 1.5 × 10^8 CFU/mL for most non-fastidious bacteria. This density standardization minimizes variability in microbial growth and minimum inhibitory concentration (MIC) readings, aligning with established antimicrobial susceptibility testing protocols. Inoculation proceeds by dipping a sterile, non-absorbent swab into the prepared suspension, rotating it against the inner wall of the tube 5-10 times to remove excess fluid, and then streaking the inoculum across the entire surface of a dried agar plate. The plate is rotated by approximately 60 degrees after each of three successive swabbings to promote even distribution and formation of a uniform microbial lawn, with the final swab run around the plate's periphery to eliminate excess moisture. The inoculated surface is allowed to dry for 3-15 minutes at ambient temperature (20-25°C) in a laminar flow hood, ensuring no visible droplets remain before proceeding. This method achieves a confluent growth essential for accurate gradient diffusion. Adjustments for specific organisms enhance reliability. Fastidious , such as streptococci or , necessitate suspensions in cation-adjusted Mueller-Hinton broth and onto supplemented media to support viability during handling. Anaerobes require preparation and within an environment (e.g., glove box or chamber with <1% oxygen) to preserve metabolic integrity, often using prereduced media. Exceptions include mucoid strains of Enterobacteriaceae, adjusted to 1.0 McFarland, or vancomycin-intermediate Staphylococcus aureus (VISA), using a 2.0 McFarland inoculum in brain-heart infusion broth for enhanced detection sensitivity. Quality assurance during inoculum preparation includes immediate verification of turbidity via direct visual comparison to a commercial 0.5 or quantitative measurement with a spectrophotometer at 625 nm (optical density 0.08-0.13). Under-inoculation risks faint growth and MIC underestimation, while over-inoculation can cause trailing endpoints; thus, suspensions should be used within 15 minutes of preparation. Reference strains, such as , are routinely tested to validate the process yields MIC values within published ranges.

Strip Application and Incubation

Strip selection for the Etest begins with choosing the appropriate antimicrobial gradient strips based on the target organism and suspected resistance patterns. For instance, vancomycin strips are commonly selected for testing Gram-positive bacteria such as staphylococci to detect vancomycin-intermediate or -resistant strains. Strips must be handled exclusively with sterile forceps to prevent contamination of the antibiotic gradient or the inoculated agar surface. The application technique involves placing the strips on the agar plate immediately after inoculation, ensuring the predefined concentration gradient is positioned correctly. Up to six strips can be applied per 150 mm plate, arranged perpendicular to one another to minimize overlap of diffusion zones and allow for clear ellipse formation; for smaller 90 mm plates, typically one to two strips are used. Strips should be centered on the inoculated surface with the MIC scale facing upward, and the edges gently pressed down using forceps to achieve full contact with the agar without disturbing the gradient or creating bubbles. This step must be completed within 15 minutes of inoculation to avoid premature diffusion of the antibiotic. Incubation follows standard guidelines to promote uniform growth and antibiotic diffusion. For most aerobic bacteria, plates are incubated aerobically at 35–37°C for 18–24 hours in ambient air using non-CO₂ incubators to maintain physiological conditions without altering pH via CO₂ supplementation. Anaerobic bacteria require incubation at 35–37°C for 48 hours in an anaerobic environment, while fungal testing, such as for yeasts on , involves 24–48 hours at 35°C under ambient air conditions. These parameters align with and recommendations, which specify 35 ± 2°C for CLSI and 35 ± 1°C for EUCAST to ensure reproducibility. To prevent agar drying, plates are stacked no higher than five, inverted during incubation to avoid condensation on the lid, and placed in humidified environments if necessary.

Result Interpretation

After incubation, the Etest plate is examined for bacterial growth inhibition around the strip, forming an elliptical zone due to the concentration gradient. The minimum inhibitory concentration (MIC) is determined by observing the point where the edge of this inhibition ellipse intersects the scale on the strip, selecting the lowest concentration value at that intersection. For zones with hazy or trailing growth, the MIC is read at the sharpest, most distinct edge of the inhibition to ensure accuracy. Special cases require careful evaluation to avoid misinterpretation. The presence of microcolonies or isolated colonies within the inhibition zone may indicate heterogeneous resistance, such as in vancomycin-intermediate Staphylococcus aureus (VISA), and warrants further confirmation using methods like population analysis profiling. If no inhibition zone forms around the strip, the MIC is reported as greater than the highest concentration on the scale, suggesting high-level resistance. Conversely, if bacterial growth extends up to or beyond the strip's edge without an observable ellipse, the MIC is less than the lowest concentration on the scale. The MIC value is recorded in micrograms per milliliter (μg/mL) as the exact reading from the strip, which may include intermediate values between standard two-fold dilutions. For clinical reporting, this MIC is interpreted against organism-specific and antimicrobial-specific breakpoints established by the Clinical and Laboratory Standards Institute (CLSI) or the European Committee on Antimicrobial Susceptibility Testing (EUCAST) to categorize the isolate as susceptible (S), susceptible with increased exposure (I), or resistant (R). These breakpoints guide therapeutic decisions, with examples including vancomycin MIC ≥16 μg/mL indicating vancomycin-resistant S. aureus (VRSA) per CLSI guidelines. Potential errors in result interpretation arise from technical issues during setup, such as uneven inoculum distribution leading to irregular or jagged inhibition ellipses, which invalidates the test and requires repetition. Plates showing no growth or confluent overgrowth across the agar are also discarded, as they prevent reliable MIC assessment; in such cases, the test must be repeated with verified inoculum density and incubation conditions.

Materials and Equipment

Agar Media and Supplements

The Etest, a gradient diffusion method for determining minimum inhibitory concentrations (MICs), relies on specific agar media to support microbial growth and ensure accurate antimicrobial diffusion. For non-fastidious aerobic bacteria, such as Enterobacteriaceae, staphylococci, enterococci, , and Acinetobacter species, the standard medium is cation-adjusted (MHA), which provides a neutral base for consistent antibiotic gradient formation and MIC readability. For fastidious aerobes, supplements are added to MHA to meet nutritional requirements. Streptococci and pneumococci require MHA supplemented with 5% sheep blood (CLSI) or 5% defibrinated horse blood plus 20 mg/L β-NAD (EUCAST, designated MH-F) to promote growth and facilitate testing. Haemophilus influenzae uses Haemophilus test medium (HTM) or MH-F agar, while Neisseria gonorrhoeae and meningitidis are tested on chocolate agar (heated blood agar) to supply essential factors like hemin and NAD. For Pseudomonas aeruginosa, cation adjustment in MHA ensures adequate calcium (20-40 mg/L) and magnesium (10-12.5 mg/L) levels, preventing underestimation of MICs for certain antibiotics. Anaerobic bacteria, including Bacteroides species, necessitate enriched media for optimal growth under oxygen-free conditions. The recommended medium is Brucella agar supplemented with 5% sheep blood, 5 μg/mL hemin, and 1 μg/mL vitamin K (or menadione), which supports the strict anaerobes' metabolic needs and maintains antibiotic stability during incubation. For yeasts such as Candida species, antifungal Etest uses RPMI 1640 medium buffered with 0.165 M morpholinepropanesulfonic acid (MOPS) and supplemented with 2% glucose, prepared as agar plates to mimic broth microdilution conditions and yield reproducible MICs. General guidelines for all Etest media include maintaining a pH of 7.2-7.4 at room temperature, verified with a surface pH electrode, to optimize antibiotic activity and microbial growth. Agar depth should be 4 ± 0.5 mm to allow proper strip placement and diffusion without excessive moisture or drying. Quality control involves testing reference strains (e.g., Escherichia coli ATCC 25922, Staphylococcus aureus ATCC 29213) on each new batch of medium, ensuring MICs fall within CLSI or EUCAST specified ranges to validate performance.

Etest Strips and Laboratory Tools

The Etest strip is a thin, inert, non-porous plastic carrier measuring 5 mm in width and 60 mm in length, designed for precise antimicrobial susceptibility testing. One side of the strip features a graduated MIC reading scale in μg/mL, while the opposite side is coated with a stable, predefined exponential gradient of antibiotic concentrations that elutes into the agar medium upon application. This gradient typically spans 15 doubling dilutions, providing a continuous range of concentrations; for example, the amoxicillin Etest strip covers 0.016 to 256 μg/mL. The strip's formulation uses dry chemistry to ensure stability and uniform diffusion, forming an elliptical inhibition zone that intersects the scale at the MIC value after incubation. Handling and application of Etest strips require specific accessories to maintain sterility and accuracy. Fine-tipped forceps are used to grasp the strips by their handles, avoiding contact with the gradient side to prevent contamination or damage. A placement template guides the positioning of up to six strips on a 150 mm plate or one to two on a 90 mm plate, ensuring equidistant radial arrangement for optimal reading of inhibition ellipses. Quality control is performed using the standard Etest strips on validated reference strains, with manufacturer-specified MIC ranges confirming strip performance and reagent integrity before clinical use. Supporting laboratory equipment enhances the efficiency and standardization of the Etest procedure. The Simplex C76 is an automated dispenser that precisely places one to six strips onto agar plates in predefined patterns, reducing manual handling errors. The Retro C80 rota-plater standardizes inoculum distribution by rotating the plate during application, achieving a uniform 0.5 McFarland turbidity equivalent for reliable results. The Nema C88 vacuum applicator uses controlled suction to securely position strips without forceps, minimizing distortion of the agar surface. Routine operations also involve a standard 35–37°C incubator for 16–20 hours of incubation and a Class II biosafety cabinet for aseptic preparation, ensuring compliance with biosafety level 2 protocols. Proper storage is essential to preserve the integrity of Etest strips, which should be stored according to the temperature specified on the packaging (typically 2–8°C, or -20°C to +8°C for single packs to extend shelf life) in their original packaging to protect against degradation from heat, light, and moisture. Desiccant pouches included in single packs (one strip each, in packs of 30) or multi-packs (100 strips) maintain humidity control, with an unopened shelf life as indicated on the label. Once opened, unused strips should be resealed and returned to appropriate storage promptly to extend usability until expiry.

Applications

Clinical Antimicrobial Susceptibility Testing

The Etest plays a central role in routine clinical antimicrobial susceptibility testing (AST) within hospital and diagnostic laboratories, where it is primarily employed to evaluate isolates from common infections such as urinary tract infections (UTIs) and bloodstream infections. By providing quantitative minimum inhibitory concentration (MIC) values, the Etest enables clinicians to select appropriate antibiotics tailored to the pathogen's susceptibility profile, particularly for challenging cases involving multidrug-resistant strains like methicillin-resistant Staphylococcus aureus (MRSA) or extended-spectrum β-lactamase (ESBL)-producing Enterobacteriaceae. This targeted approach helps optimize therapy for infections where empirical treatment may fail, reducing the risk of treatment escalation and prolonged hospital stays. In clinical workflows, the Etest complements qualitative methods such as disk diffusion and quantitative reference techniques like broth microdilution, offering a practical alternative when precise MIC determination is required for pharmacokinetic/pharmacodynamic (PK/PD) optimization. For instance, in endocarditis caused by staphylococci, Etest-derived vancomycin MICs guide dosing adjustments to achieve therapeutic targets, such as an area under the curve (AUC) to MIC ratio of 400–600, which is critical for efficacy against severe infections. This integration enhances laboratory efficiency, as the Etest can be performed alongside automated systems like VITEK 2 for non-fastidious and fastidious organisms, ensuring rapid turnaround without compromising accuracy. Etest results directly correlate with standardized breakpoints from organizations like the Clinical and Laboratory Standards Institute (CLSI) and the European Committee on Antimicrobial Susceptibility Testing (EUCAST), facilitating clear categorization of isolates as susceptible, intermediate, or resistant to inform susceptibility reports. For example, an MIC of ≤0.25 μg/mL for ciprofloxacin against indicates susceptibility per current CLSI guidelines, allowing confident use of the agent for uncomplicated UTIs, while higher values prompt alternative choices. Since its FDA clearance in 1991 as a diagnostic tool for bacterial susceptibility, the Etest has become integral to antimicrobial stewardship programs, supporting efforts to curb resistance by promoting judicious antibiotic use based on evidence-based MIC data.

Research and Non-Clinical Uses

The Etest has been extensively employed in research settings for epidemiological surveillance of antimicrobial resistance patterns, enabling precise determination of minimum inhibitory concentrations (MICs) in large-scale studies of bacterial isolates from diverse sources. For instance, it has facilitated the characterization of resistance profiles in commensal from food-producing animals in Qatar, revealing high levels of multidrug resistance that inform regional surveillance efforts. Similarly, in hospital-based molecular epidemiology studies, the Etest has been combined with pulsed-field gel electrophoresis to track methicillin-resistant clones and their susceptibility patterns, aiding in the identification of resistance trends over time. In the evaluation of novel antimicrobials or combinations, the Etest provides a reliable gradient diffusion method to assess in vitro activity against challenging pathogens. Researchers have used it to investigate the synergistic effects of colistin and tigecycline against multidrug-resistant Acinetobacter baumannii, demonstrating reduced MICs in combination testing that highlight potential therapeutic strategies. For studies on biofilm-forming bacteria, the Etest has been adapted to quantify susceptibility in biofilm models, such as those involving Pseudomonas aeruginosa, where it revealed elevated MICs compared to planktonic cells, underscoring the role of biofilms in persistence. These applications leverage the Etest's precision in generating continuous MIC scales, making it suitable for comparative analyses in academic and pharmaceutical research. Beyond human health, the Etest finds utility in non-clinical contexts, including veterinary microbiology for assessing antibiotic resistance in animal pathogens. It has been validated for direct susceptibility testing of bacteria from equine synovial fluid infections, offering rapid and accurate MIC results for pathogens like Streptococcus equi subsp. zooepidemicus with 91% categorical agreement to reference methods. In environmental testing, the Etest supports the analysis of antibiotic resistance in soil microbes, as demonstrated in studies examining tetracycline and sulfonamide resistance in bacteria from agricultural soils under varying management practices, where it helped quantify resistance prevalence influenced by land use. Additionally, for antifungal testing in agricultural settings, the Etest has been applied to evaluate susceptibility of Candida species isolated from poultry, identifying patterns of resistance to azoles and amphotericin B that impact animal health and food safety. Specialized research employs the Etest to assess MIC shifts under stress conditions, such as variations in pH or nutrient availability, providing insights into bacterial adaptability. For example, testing on media adjusted to different pH levels has shown how environmental factors alter susceptibility in fungi like Candida, with MICs increasing at acidic pH, which is relevant for understanding resistance in variable ecosystems. In academic laboratories, the Etest has been instrumental in validating new clinical breakpoints for antimicrobials like tigecycline against Enterobacteriaceae and staphylococci, achieving high reproducibility (essential agreement >95%) across multicenter evaluations that support updated interpretive criteria. These non-clinical uses extend the Etest's role in global resistance monitoring, including contributions to networks like national surveillance systems aligned with objectives, and its adaptability for screening in pharmaceutical R&D where precise MIC data accelerates compound evaluation. Recent developments include the FDA clearance of the ETEST Imipenem/Relebactam strip for P. aeruginosa in 2025, enhancing options for evaluating novel combinations against resistant pathogens.

Advantages and Limitations

Key Benefits

The Etest method offers high precision in determining minimum inhibitory concentrations (MICs) by utilizing plastic strips impregnated with a predefined exponential gradient of antibiotic concentrations, spanning up to 15 twofold dilutions from 0.002 to 256 µg/mL depending on the agent, which allows for the detection of subtle resistance levels that qualitative methods like disk diffusion cannot resolve. Unlike disk diffusion, which provides only categorical interpretations (susceptible, intermediate, or resistant) based on inhibition zone diameters, the Etest generates quantitative MIC values directly from the elliptical inhibition zone intersection with the strip, enabling more accurate pharmacodynamic assessments and tailored dosing decisions. This quantitative approach has demonstrated essential agreement rates exceeding 90% with reference broth microdilution methods across various pathogens, ensuring reliable MIC endpoints for clinical guidance. Particularly advantageous for fastidious organisms, the Etest simplifies susceptibility testing compared to labor-intensive broth-based methods, as it requires only agar inoculation and strip placement without the need for specialized liquid media handling that can challenge growth of species like Streptococcus pneumoniae or nutritionally variant streptococci. The method's compatibility with Mueller-Hinton agar supplemented appropriately supports the growth requirements of these organisms under standard aerobic conditions, yielding interpretable MICs in a single incubation step, which reduces technical variability associated with preparing dilutions for fastidious strains. For instance, studies on S. pneumoniae have validated its use for key antibiotics like penicillin and ceftriaxone, confirming its utility in detecting reduced susceptibility in respiratory isolates. In terms of efficiency, the Etest enables a streamlined workflow with a single-plate setup where up to six strips can be applied per , delivering MIC results typically within 18-24 hours of incubation, making it suitable for urgent clinical scenarios without requiring automated systems. This targeted testing approach is cost-effective for selective use, as it avoids the need for full-panel while providing precise data for specific antibiotics of interest, thereby optimizing resource allocation in resource-limited laboratories. Reproducibility is enhanced by the standardized of Etest strips, which minimizes inter-laboratory variability and ensures consistent delivery, with validation studies reporting over 95% agreement in values against CLSI reference methods for common Gram-positive and . Intra-laboratory repeatability is high, often within ±1 log2 dilution, supporting its adoption for in programs.

Potential Drawbacks and Quality Control

One primary limitation of the Etest method is its elevated cost relative to disk diffusion testing, making it less economical for routine high-volume screening. Additionally, Etest strips are manufactured with predefined antibiotic concentration gradients, restricting their use to commercially available antimicrobials and precluding customization for emerging or non-standard agents. The technique can also produce trailing endpoints, especially in scenarios involving heterogeneous resistance, where minor resistant subpopulations cause gradual rather than sharp inhibition patterns, complicating precise MIC interpretation. Etest results are highly susceptible to procedural variables, including inaccuracies in inoculum standardization (targeting 0.5 McFarland turbidity), inconsistencies in Mueller-Hinton composition or depth, and deviations in or (typically 35–37°C for 16–20 hours). These factors can distort the inhibition ellipse, leading to unreliable values. Furthermore, Etest performs poorly with polymyxins such as and polymyxin B due to their inadequate through media, often yielding falsely susceptible results and essential agreement rates below 90% compared to reference . Quality control measures are critical to mitigate these issues and validate Etest performance. Laboratories must conduct daily or per-session testing with reference strains, such as ATCC 25922, which exhibits an expected of 2–8 μg/mL for under standard conditions. Additional verification includes inspecting the inhibition ellipse for symmetry (minimal distortion at the strip ends) and edge sharpness (clear 80% growth inhibition without haze), ensuring proper strip application perpendicular to the agar surface and absence of air bubbles. Post-2021 developments in antimicrobial susceptibility testing have emphasized rapid phenotypic approaches, but Etest has seen limited direct adaptations for acceleration, retaining its conventional 18–24-hour timeline; nonetheless, new strip formulations for emerging threats like multidrug-resistant Gram-negatives have enhanced its targeted utility, including the 2025 FDA-cleared Etest /Avibactam strips (MIC range 0.016/4–256/4 μg/mL), which show >95% essential agreement with reference methods for . For high-throughput environments, Etest complements automated platforms like VITEK 2, which provide faster categorical results but may exhibit lower essential agreement (around 82–87%) for certain antibiotics, positioning Etest as a confirmatory tool for precise in complex cases.

History and Development

Origins and Invention

The origins of the Etest trace back to the foundational work of medical microbiologist Hans Ericsson at the in the 1950s and 1960s, where he refined the disk method to enable more quantitative determination of minimum inhibitory concentrations (s) for antibiotics. Ericsson's approach emphasized and gradient-based to improve the precision of susceptibility testing beyond qualitative zone measurements, addressing inconsistencies in early assays. His efforts, detailed in key publications, laid the groundwork for later innovations by promoting reproducible MIC readings through controlled principles. Building on these concepts, the Etest was developed in the late by researchers at AB BIODISK, a diagnostics founded in the following Ericsson's research. The method was first described in 1988 as a plastic strip impregnated with a predefined exponential of concentrations, designed to combine the simplicity of tests with the accuracy of dilution methods for determination. Prototype evaluations focused on common pathogens such as staphylococci and enterobacteria, testing the strip's performance on plates to ensure stable elution and reliable inhibition ellipse formation. Initial validation studies compared Etest results to reference dilution techniques, revealing high concordance with approximately 90% essential agreement (±1 log2 dilution) in values across tested antimicrobials and bacterial strains. This agreement underscored the method's potential for clinical use, particularly for Gram-positive and Gram-negative aerobes, while highlighting Ericsson's enduring influence on quantitative testing innovations.

Commercialization and Advancements

The Etest received U.S. (FDA) clearance in 1991 as the first commercial gradient diffusion method for determining minimum inhibitory concentrations (MICs) of antimicrobials against . AB BIODISK commercialized the product, initially providing strips for approximately 20 antimicrobials to support susceptibility testing in clinical laboratories. In 2008, acquired AB BIODISK, facilitating further global expansion and integration of the Etest into its diagnostic portfolio. By the 2000s, the product line had expanded significantly, offering over 100 strip types that included antifungals and combinations for detecting resistance mechanisms such as extended-spectrum beta-lactamases. In the 2010s, integration with automated systems advanced its utility; for example, the BIOMIC V3 reader enabled standardized digital interpretation of Etest results, complementing platforms like VITEK 2 for enhanced workflow efficiency. Protocols for direct Etest application from positive blood cultures, yielding MIC results in 5-6 hours, were also developed during this period to support timely therapy decisions. Post-2021 developments focused on accelerating testing amid rising concerns. Digital reading applications further improved precision in MIC assessment, while Etest strips were adapted for tracking resistance in secondary bacterial infections during the , aiding surveillance of multidrug-resistant pathogens in affected patients. Recent additions include strips for newer agents such as /avibactam, sulbactam/durlobactam, and imipenem/relebactam, supporting as of 2023. Etest plays a key role in harmonizing susceptibility testing guidelines from organizations like the European Committee on Antimicrobial Susceptibility Testing (EUCAST) and the Clinical and Laboratory Standards Institute (CLSI).