Sorbitol-MacConkey agar
Sorbitol-MacConkey agar (SMAC) is a selective and differential culture medium employed in microbiology for the isolation and presumptive identification of enterohemorrhagic Escherichia coli serotype O157:H7, a significant foodborne pathogen linked to outbreaks of hemorrhagic colitis and hemolytic uremic syndrome, particularly in children and the elderly.[1] This medium modifies the classic MacConkey agar formula by substituting sorbitol for lactose as the key fermentable carbohydrate, enabling differentiation of sorbitol-nonfermenting strains like O157:H7, which appear as colorless colonies, from sorbitol-fermenting E. coli strains that produce pink to red colonies due to acid production and neutral red indicator uptake.[2][3] Developed in 1986, SMAC is widely used for the initial screening of E. coli O157:H7 in clinical, food, and environmental samples, though confirmatory tests are required and variants may be employed to improve selectivity.[4][2][5]Background
Relation to MacConkey Agar
MacConkey agar, developed by bacteriologist Alfred Theodore MacConkey in 1900, serves as a foundational selective and differential medium for isolating and identifying gram-negative enteric bacteria, particularly through their ability to ferment lactose.[6][7] The medium's selectivity stems from bile salts and crystal violet, which inhibit the growth of gram-positive organisms, while neutral red acts as a pH indicator to differentiate lactose-fermenting bacteria—appearing as pink colonies due to acid production—from non-fermenters, which form colorless colonies.[7] Sorbitol-MacConkey agar modifies this standard formulation by substituting sorbitol for lactose as the key fermentable carbohydrate, enabling differentiation based on sorbitol utilization rather than lactose. This change targets non-sorbitol-fermenting pathogens, such as certain enterohemorrhagic strains of Escherichia coli, which produce colorless colonies on the medium, while sorbitol fermenters develop pink colonies. The core selective elements—bile salts and crystal violet for gram-positive inhibition, along with neutral red as the pH indicator—are preserved from the original MacConkey agar to maintain its utility for gram-negative enteric isolation.[8] This adaptation addresses limitations in standard MacConkey agar for gut-related clinical samples, where lactose fermentation is common among most enteric bacteria, providing enhanced specificity for detecting rare non-sorbitol-fermenting pathogens like E. coli O157:H7 without altering the medium's fundamental selective properties.Development History
Sorbitol-MacConkey agar originated from early efforts in the mid-20th century to improve the isolation of specific enteropathogenic Escherichia coli strains, building on the foundational selective and differential properties of MacConkey agar developed in the early 1900s for enteric bacteria. In 1952, Fritz Rappaport and Eva Henig formulated the initial medium by replacing lactose with sorbitol in a MacConkey agar base, aiming to differentiate sorbitol-fermenting strains from non-fermenters among serotypes O111 and O55, which were emerging causes of infantile diarrhea. This innovation leveraged sorbitol as a carbon source to produce distinct colony morphologies, facilitating targeted isolation in clinical samples. The medium saw limited use initially but gained renewed attention in the 1980s amid rising outbreaks of severe foodborne illness linked to Shiga toxin-producing E. coli. The pathogen E. coli O157:H7 was first identified in 1982 during investigations of hemorrhagic colitis cases in the United States, often progressing to hemolytic uremic syndrome, prompting the need for better detection tools as traditional media failed to distinguish this sorbitol-nonfermenting strain from normal flora. In response, the agar was adapted for broader application in isolating O157:H7 from stool and food sources, capitalizing on its inability to ferment sorbitol while most other E. coli strains could. A pivotal advancement came in 1986 when Stephen B. March and Shirish Ratnam validated and popularized the sorbitol-substituted MacConkey agar through rigorous testing, demonstrating its high sensitivity and specificity for detecting O157:H7 in clinical stools and ground beef samples associated with hemorrhagic colitis outbreaks. Their work established the medium as a standard for routine screening, reporting isolation rates exceeding 90% in confirmed cases and emphasizing its simplicity over serological methods. Further refinements in the early 1990s enhanced selectivity against competing sorbitol-nonfermenting bacteria. In 1993, Paul M. Zadik, P. A. Chapman, and C. A. Siddons introduced cefixime-tellurite supplementation to the base agar, creating cefixime-tellurite Sorbitol-MacConkey (CT-SMAC) medium, which inhibited non-O157 strains and improved recovery of verocytotoxigenic E. coli O157 from environmental and food matrices without compromising target growth. This modification addressed limitations in overcrowded plates and became widely adopted in public health laboratories for enhanced pathogen surveillance.Composition and Preparation
Key Ingredients
Sorbitol-MacConkey agar relies on a precise blend of ingredients to support the growth of Gram-negative bacteria while providing mechanisms for selectivity against Gram-positives and differentiation based on sorbitol fermentation. The nitrogen sources consist of pancreatic digest of casein at 17 g/L and peptic digest of animal tissue at 3 g/L, which furnish essential amino acids, peptides, and nitrogen compounds required for the proliferation of enteric pathogens like Escherichia coli.[9] The fermentable carbohydrate D-sorbitol is incorporated at 10 g/L, serving as the primary substrate for acid production to differentiate sorbitol-fermenting strains from non-fermenters such as E. coli O157:H7, which fail to produce acid and thus do not alter the medium's pH indicator.[9] Sodium chloride is added at 5 g/L to maintain osmotic equilibrium, simulating physiological conditions and preventing plasmolysis in target bacteria.[9] For selectivity, bile salts at 1.5 g/L and crystal violet at 0.001 g/L inhibit Gram-positive organisms by disrupting their cell membranes and binding to cellular components, respectively, thereby enriching the medium for Gram-negative enterobacteria.[3] Neutral red, present at 0.03 g/L, acts as the pH indicator, remaining colorless or pink in neutral to alkaline environments but shifting to red under acidic conditions generated by sorbitol metabolism.[9] Agar at 13.5 g/L provides the gelling agent to create a solid surface for colony formation and morphological assessment.[9] The medium's final pH is adjusted to 7.1 ± 0.2 at 25°C, ensuring optimal bacterial growth and indicator sensitivity.[9]Preparation Procedure
The preparation of Sorbitol-MacConkey agar begins by suspending approximately 50 g of the dehydrated medium powder in 1 L of distilled water.[10] This mixture is then heated to boiling while stirring continuously to ensure complete dissolution of all components, with care taken to avoid overheating, which could degrade the sorbitol.[11] The dissolved medium is autoclaved at 121°C for 15 minutes under 15 psi pressure to achieve sterility.[10] After autoclaving, the medium is allowed to cool to 45-50°C in a water bath, at which point it is thoroughly mixed to ensure homogeneity before being aseptically dispensed into sterile Petri plates, typically 20-25 mL per 90 mm plate.[11] The plates are permitted to solidify at room temperature and the surface is dried briefly (e.g., by leaving the lids ajar in a laminar flow hood) to prevent condensation, after which they are stored inverted at 4-8°C until use, remaining stable for up to several weeks.[10] For variations such as cefixime-tellurite supplemented Sorbitol-MacConkey (CT-SMAC) agar, the antibiotics are added to the cooled medium (below 55°C) post-autoclaving to maintain their activity, followed by immediate pouring into plates. Standard laboratory safety protocols should be followed throughout, including the use of personal protective equipment and operation within a biosafety cabinet to minimize contamination risks.[11]Principle
Selective Properties
Sorbitol-MacConkey agar (SMAC) functions as a selective medium by incorporating bile salts, crystal violet, and sodium chloride to inhibit the growth of gram-positive bacteria, certain gram-negative contaminants, and fastidious organisms, thereby enriching for enteric gram-negative bacteria such as Enterobacteriaceae.[11] Bile salts, at a concentration of 1.5 g/L, exert their selective effect by disrupting the cell membranes of gram-positive bacteria through emulsification of lipids, a process facilitated by their amphipathic nature that targets the exposed lipid components lacking the protective outer membrane found in gram-negatives.[11][12][6] Crystal violet, included at 0.001 g/L, binds preferentially to the thicker peptidoglycan layer of gram-positive bacteria, interfering with cell wall synthesis and thereby inhibiting their replication at these low concentrations.[11][13] The addition of 5 g/L sodium chloride introduces osmotic stress, creating a high osmotic pressure environment that limits the growth of non-adapted contaminants, including some gram-positive and fastidious species.[11] Collectively, these agents suppress gram-positive bacteria and certain fastidious organisms, allowing robust growth of target enteric gram-negatives.[11]Differential Properties
Sorbitol-MacConkey agar differentiates bacteria based on their ability to ferment sorbitol as the primary carbohydrate source, replacing lactose in the standard MacConkey formulation. Organisms capable of sorbitol fermentation metabolize it to produce acids, which lower the pH of the surrounding medium below 6.8. This acidification is detected by the neutral red indicator, which shifts from its neutral yellow or off-white color to pink or red under acidic conditions, resulting in pink to red colonies for fermenting strains.[14][7] In contrast, non-sorbitol-fermenting bacteria, such as Escherichia coli O157:H7, do not produce sufficient acids and thus fail to lower the pH significantly. These non-fermenters form colorless or pale, translucent colonies on the agar surface, providing a clear visual distinction from the surrounding growth. The background of the plate often appears pink due to the proliferation of sorbitol-fermenting enteric flora in the sample, which further enhances the contrast and facilitates the isolation of non-fermenting colonies.[14][15] This metabolic differentiation relies on the selective inhibition by bile salts, which permits only enteric bacteria to grow and undergo the sorbitol fermentation test. The neutral red indicator's sensitivity to pH changes around 6.8 ensures reliable detection without interference from non-target organisms.[7]Applications
Primary Use in Pathogen Detection
Sorbitol-MacConkey agar (SMAC) serves as a cornerstone in the primary detection of verotoxin-producing Escherichia coli (VTEC) serotype O157:H7, a major enterohemorrhagic strain responsible for severe gastrointestinal infections, from diverse sample types including clinical stool specimens, food products such as ground beef, and environmental sources like water.[3][16] This medium enables the selective isolation of O157:H7 by exploiting its inability to ferment sorbitol, distinguishing it from most other E. coli strains that produce pink colonies.[3] In the United States, STEC O157 infections, predominantly caused by O157:H7, result in an estimated 86,000 illnesses annually (24% of total STEC illnesses, based on 2019 data updated in 2025), often manifesting as bloody diarrhea accompanied by severe abdominal cramps, with approximately 5-10% progressing to hemolytic uremic syndrome (HUS), a life-threatening condition involving kidney failure.[17][18] Detection protocols typically begin with sample processing tailored to the source material; for instance, stool from patients with bloody diarrhea is directly inoculated, while food or water samples with potentially low pathogen loads undergo pre-enrichment in selective broth such as tryptic soy broth with bile salts to enhance bacterial recovery before plating.[19][16] Inoculation involves streaking or spreading a diluted sample suspension onto the agar surface to obtain isolated colonies, followed by aerobic incubation at 35-37°C for 18-24 hours.[3][16] Suspect colonies appear colorless or pale, prompting further confirmation via serological testing for O157 antigen and biochemical assays.[16] Since the 1980s, following the initial recognition of O157:H7 in hemorrhagic colitis outbreaks, SMAC has been integrated into CDC-recommended protocols for routine screening in clinical laboratories and public health investigations, facilitating rapid identification during multistate foodborne incidents linked to contaminated beef or produce.[3][16] This approach supports timely epidemiological tracing and intervention, underscoring SMAC's role in mitigating the public health impact of an estimated 1,700 hospitalizations and most of the 66 deaths from STEC each year in the US, with O157 responsible for the majority of severe outcomes.[17]Additional Clinical and Food Safety Roles
Beyond its primary role in detecting Escherichia coli O157:H7, Sorbitol-MacConkey agar facilitates the identification of other sorbitol-nonfermenting enteropathogenic E. coli (EPEC) serotypes, such as O55, which are implicated in infant diarrhea cases. These serotypes often exhibit delayed or absent sorbitol fermentation, appearing as colorless colonies on the medium, allowing differentiation from sorbitol-fermenting strains. Originally developed for isolating EPEC serotypes like O11 and O55 associated with infantile gastroenteritis, the agar has been employed in clinical settings to screen stool samples from affected infants, aiding in the epidemiological investigation of outbreaks. However, for broader STEC detection including non-O157 serogroups, molecular assays are increasingly recommended alongside SMAC, as per current CDC protocols.[20][21][22][17] In food microbiology, Sorbitol-MacConkey agar, often supplemented with cefixime and tellurite (CT-SMAC), supports screening for E. coli O157 in various matrices including dairy products, meat, and produce, as outlined in the ISO 16654 standard. The method involves enrichment in modified tryptic soy broth followed by immunomagnetic separation and plating on CT-SMAC, where non-sorbitol-fermenting colonies indicate potential pathogens, with detection limits as low as 1-2 CFU/25 g in inoculated milk products after appropriate incubation. This application ensures compliance with international food safety protocols by enabling rapid isolation from complex food samples, thereby preventing contamination spread in the supply chain.[23][24] Veterinary applications extend to monitoring animal reservoirs, particularly in cattle feces, where the agar is used to detect sorbitol-fermenting or non-fermenting Shiga toxin-producing E. coli O157 strains that serve as zoonotic sources. Isolation protocols typically combine immunomagnetic separation with plating on Sorbitol-MacConkey agar to identify presumptive colonies from fecal samples, revealing prevalence in dairy herds and water troughs as potential transmission points to humans. Such surveillance helps in managing on-farm biosecurity to mitigate public health risks from livestock.[25][26] In research, Sorbitol-MacConkey agar serves as a tool for investigating sorbitol metabolism within Enterobacteriaceae, particularly by observing colony morphology and fermentation patterns that reflect metabolic variations. Studies have utilized the medium to characterize acid and heat tolerance in E. coli O157:H7 mutants, noting differences in mucoid colony formation linked to sorbitol utilization pathways, and to assess color intensity variations among sorbitol-fermenting strains. This enables deeper insights into the biochemical diversity and virulence factors of enteric bacteria.[27][28]Results and Interpretation
Colony Characteristics
On Sorbitol-MacConkey (SMAC) agar, Escherichia coli O157:H7, which does not ferment sorbitol, produces colorless to pale gray, flat colonies measuring 1-2 mm in diameter, often with a smoky center, after 18-24 hours of incubation at 35-37°C.[29][4] In contrast, sorbitol-fermenting coliforms such as typical E. coli strains form pink to red colonies due to acid production from sorbitol fermentation, which lowers the pH and causes the neutral red indicator to shift from colorless to red, often accompanied by a bile precipitate.[29][3] Non-sorbitol-fermenting pathogens like Salmonella spp. and Shigella spp. also appear as colorless colonies on SMAC agar, similar to E. coli O157:H7, but are typically distinguished through additional biochemical or serological tests.[7][30] Optimal colony development occurs after 24 hours of incubation; over-incubation beyond this period can lead to fading of the pink color in sorbitol-fermenting colonies or subtle pink tinting in some non-fermenters, complicating interpretation.[31] The neutral red indicator's pH-dependent color change (red below pH 6.8, colorless above) underlies these differential appearances.[3]Quality Control Measures
Quality control measures for Sorbitol-MacConkey agar ensure the medium's reliability in selectively isolating and differentiating enterohemorrhagic Escherichia coli strains, particularly O157:H7, by validating growth promotion, inhibition, and biochemical reactions using standardized reference strains. These protocols, aligned with guidelines such as those in CLSI document M22-A3 for microbiological media quality control, require testing each new batch or lot of prepared medium before routine use to confirm performance consistency.[32] Visual and sterility checks are performed initially, including verification of pH (7.1 ± 0.2 at 25°C), uniform color, and depth, followed by inoculation with control organisms incubated at 35-37°C for 18-24 hours.[31] Positive controls utilize sorbitol-fermenting E. coli strains to confirm differential fermentation, producing pink to red colonies due to acid production from sorbitol metabolism and indicator dye change. A representative example is E. coli ATCC 8739, which exhibits good growth with pink colonies.[33] Similarly, E. coli ATCC 25922 serves as an alternative positive control, yielding pink colonies.[11] Negative controls employ sorbitol-nonfermenting strains to verify the absence of color change, resulting in colorless or transparent colonies. E. coli O157:H7 ATCC 43888 is a standard negative control, demonstrating growth with colorless colonies.[34] Another option is E. coli O157:H7 ATCC 35150, which also forms colorless colonies without sorbitol fermentation.[31] Selectivity is assessed using gram-positive and non-enteric organisms to ensure inhibition by bile salts and crystal violet. Staphylococcus aureus ATCC 25923 shows partial to complete inhibition with no significant growth, confirming the medium's suppression of contaminants.[34] Additional checks may include Enterococcus faecalis ATCC 29212 for inhibited growth.[32] Prepared plates are stored at 2-8°C, protected from light, and remain stable for up to 12 weeks or until the expiration date, provided they are kept upright to avoid moisture condensation.[31] Prior to use, inspect for dehydration (e.g., cracking or shrinking), discoloration, or contamination; discard if any deterioration is evident. Testing frequency includes evaluation of each batch upon receipt and preparation, with periodic retesting for extended storage as per laboratory protocols.[32]| Control Type | Reference Strain | Expected Result | Source |
|---|---|---|---|
| Positive (sorbitol-fermenting) | E. coli ATCC 8739 | Growth, pink colonies | [33] |
| Positive (sorbitol-fermenting) | E. coli ATCC 25922 | Growth, pink colonies | [11] |
| Negative (sorbitol-nonfermenting) | E. coli O157:H7 ATCC 43888 | Growth, colorless colonies | [34] |
| Negative (sorbitol-nonfermenting) | E. coli O157:H7 ATCC 35150 | Growth, colorless colonies | [31] |
| Selectivity (gram-positive inhibition) | S. aureus ATCC 25923 | Partial to complete inhibition, no growth | [34] |