Bactec Mgit 960 System User's Manual

Mycobacteria Growth Indicator Tube (MGIT) is intended for the detection and recovery of mycobacteria. The MGIT Mycobacteria Growth Indicator Tube contains 4 mL of modified Middlebrook 7H9 Broth base. The complete medium, with OADC enrichment and PANTA antibiotic mixture, is one of the most commonly used liquid media for the cultivation of mycobacteria.

  1. Bactec Mgit 960 System User's Manual Software
  2. Bactec Mgit 960 Specifications

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All types of clinical specimens, pulmonary as well as extra-pulmonary (except blood and urine), can be processed for primary isolation in the MGIT tube using conventional methods. After processed specimen is inoculated, MGIT tube must be continuously monitored either manually or by automated instruments until positive or the end of the testing protocol.

  • 2Instruments

Principles of the Procedure[edit]

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A fluorescent compound is embedded in silicone on the bottom of 16 × 100 mm round bottom tubes. The fluorescent compound is sensitive to the presence of oxygen dissolved in the broth. Initially, the large amount of dissolved oxygen quenches emissions from the compound and little fluorescence can be detected. Later, actively respiring microorganisms consume the oxygen and allow the fluorescence to be detected.

Tubes are filled with samples in the broth and continuously incubated at 37°C. The tubes are monitored for increasing fluorescence to determine if the tube is instrument positive; i.e., the test sample contains viable organisms. Fluorescence can be recorded by automated instruments such as Becton Dickinson's BACTEC MGIT 960 System, or manually using the BD BACTEC microMGIT fluorescence reader or a Wood's lamp or other long-wave UV light source.[1]

Instruments[edit]

BACTEC MGIT 960 System[edit]

This instrument is produced by Becton Dickinson (BD). It is specially designed to accommodate Mycobacteria Growth Indicator Tube (MGIT) and incubate them at 37°C. The instrument scans the MGIT every 60 minutes for increased fluorescence. Analysis of the fluorescence is used to determine if the tube is instrument positive; i.e., the test sample contains viable organisms. An instrument-positive tube contains approximately 105 to 106 colony-forming units per milliliter (CFU/mL). Culture tubes which remain negative for a minimum of 42 days (up to 56 days) and which show no visible signs of positivity are removed from the instrument as negatives and discarded.[2] Its usefulness has been evaluated in the scientific literature.[3][4][5]

References[edit]

  1. ^Siddiqi, Salman H.; Sabine Rüsch-Gerdes (2006). Procedure Manual For BACTEC MGIT 960 TB System.
  2. ^Siddiqi, Salman H.; Sabine Rüsch-Gerdes (2006). Procedure Manual For BACTEC MGIT 960 TB System.
  3. ^'Use of BACTEC MGIT 960 for Recovery of Mycobacteria from Clinical Specimens: Multicenter Study' Enrico Tortoli, Paola Cichero, Claudio Piersimoni, M. Tullia Simonetti, Giampietro Gesu, and Domenico Nista Journal of Clinical Microbiology, November 1999, p. 3578-3582, Vol. 37, No. 11 [1]
  4. ^'Evaluation of Automated BACTEC MGIT 960 System for Testing Susceptibility of Mycobacterium tuberculosis to Four Major Antituberculous Drugs: Comparison with the Radiometric BACTEC 460TB Method and the Agar Plate Method of Proportion' Enrico Tortoli, Marta Benedetti, Alessandra Fontanelli, and M. Tullia Simonetti Journal of Clinical Microbiology, February 2002, p. 607-610, Vol. 40, No. 2 doi:10.1128/JCM.40.2.607-610.2002
  5. ^'Evaluation of the fully automated Bactec MGIT 960 system for the susceptibility testing of Mycobacterium tuberculosis to first-line drugs: a multicenter study' Fanourios Kontosa, Maria Maniatia, Christos Costopoulosb, Zoe Gittic, Stavroula Nicolaoub, Efymia Petinakia, Spyridoula Anagnostoub, Ioannis Tselentisc and Antonios N. Maniatis Journal of Microbiological Methods Volume 56, Issue 2, February 2004, Pages 291–294 doi:10.1016/j.mimet.2003.10.015
Retrieved from 'https://en.wikipedia.org/w/index.php?title=Mycobacteria_growth_indicator_tube&oldid=865812479'
Published online 2009 Nov 18. doi: 10.1128/JCM.01775-09
PMID: 19923479
This article has been cited by other articles in PMC.

Abstract

During susceptibility testing of 743 isolates of Mycobacterium tuberculosis to pyrazinamide (PZA) using the Bactec 960 system, 57 (7.7%) isolates showed PZA resistance. Repeat testing of resistant isolates with the Bactec 460 reference method confirmed 33 (4.4%) of these isolates as resistant, and 24 (3.2%) were susceptible. Erroneous results for resistance with the Bactec 960 were confirmed by testing the 24 discordant isolates for pyrazinamidase and mutations in the pncA gene.

Pyrazinamide (PZA) is an important component of the multidrug regimen used to treat tuberculosis (TB). With increasing worldwide prevalence of drug-resistant TB, it is vital for laboratories to accurately detect resistance to first-line antimicrobials.

The CLSI-recommended method for PZA testing (4) is the Bactec 460TB radiometric system (Becton Dickinson, Sparks, MD). Most laboratories have now replaced the 460TB system with the nonradiometric Bactec MGIT 960 (BT960) system (Becton Dickinson, Sparks, MD). Both methods utilize an acidified Middlebrook broth and a critical concentration of 100 μg/ml.

Bactec Mgit 960 System User's Manual Software

PZA is a prodrug which in Mycobacterium tuberculosis is converted to its active form, pyrazinoic acid (POA), by the enzyme pyrazinamidase (PZase) (, ). The absence of a functional PZase enzyme in an M. tuberculosis strain therefore indicates resistance to PZA. The pncA gene coding for PZase in M. tuberculosis has been sequenced, and mutations in this gene have been shown to be responsible for resistance to PZA (, , ). Tests both for PZase activity and for the detection of mutations in pncA may be utilized as alternative methods for the detection of PZA resistance in M. tuberculosis.

All new M. tuberculosis isolates are tested for susceptibility to first-line drugs, including PZA, at the Public Health Laboratory, Toronto. During the report period, any isolate demonstrating PZA resistance by the BT960 was retested using the 460TB. If the 460TB PZA result was discordant, these isolates were further tested for the presence of PZase activity and mutations in the pncA gene, and testing in the BT960 was repeated.

PZA susceptibility testing in the BT960 system was performed according to the manufacturer's instructions (2). Briefly, isolates of M. tuberculosis in Mycobacteria Growth Indicator Tubes (MGITs) were used as the test inocula. A drug-free control tube was inoculated with a 1:10 dilution of the inoculum, and the PZA test tube was inoculated with 0.5 ml of the inoculum and 0.1 ml of PZA. The tubes were monitored with the BT960 instrument until the growth control tube flagged positive. At that time, the instrument read the PZA test tube as either resistant (growth unit [GU] ≥ 100) or susceptible (GU < 100). A blood agar purity plate from the inoculum was incubated for 3 days.

PZA testing in the BT 460TB system was performed according to the manufacturer's instructions (13). Briefly, a drug-free control vial and the PZA test vial were each inoculated with 0.1 ml of inoculum from an actively growing culture. The vials were incubated and were read on the BT460 instrument daily until the growth index (GI) in the control vial was ≥200. At that time, the GI in the test vial was calculated as a percentage of the GI in the control. A result of ≥11% indicated resistance, <9% indicated susceptibility, and from 9 to 11% was borderline. A blood agar purity plate from the inoculum was incubated for 3 days.

Isolates with results that were discordant between the two systems were tested for the presence of PZase activity and for mutations in the pncA gene at the National Reference Centre for Mycobacteriology, Winnipeg, Manitoba, Canada, by standard methodologies (, ) and with repeat testing in the BT960.

During the report period, 743 PZA susceptibility tests were performed using the BT960. Of these, 57 (7.7%) showed PZA resistance. Thirty-three of these isolates were confirmed to be PZA resistant using the Bactec 460 system and were eliminated from the discordant-data analysis. The remaining 24 PZA-resistant isolates (3.2% of the total) were susceptible to PZA with the 460TB and were considered discordant. Follow-up testing of these isolates showed the presence of PZase in all isolates, and all were negative for mutations in the pncA gene. Repeat PZA testing of the discordant isolates with the BT960 gave a second resistant result for 10 isolates and a susceptible result for 14 isolates, indicating lack of reproducibility. The 460TB result was considered the gold standard for reporting results.

There are reports citing technical problems with in vitro testing of M. tuberculosis with PZA. None of the methods described give 100% agreement when compared with the 460TB reference method, and most cite problems with false resistance (, , , ).

The effects of inoculum concentration, volume, and homogeneity, as well as the lack of reproducibility in BT960 PZA tests, have been cited (, , , ). However, we are not aware of a study where BT960-resistant strains were tested with the 460TB plus PZase and molecular testing.

There are several differences in the inocula used for testing PZA in the two systems. First, in the 460TB, the ratio of inoculum to medium is 1:42, whereas in the BT960 system, the ratio is 1:16.6. The concentration of inoculum in the test medium in the BT960 is thus more than 2.5 times greater than that used in the 460TB. The volume of inoculum used in the BT960 is 0.5 ml, versus 0.1 ml of inoculum used in the 460TB. The higher concentration and volume of inoculum used in the BT960 has a higher likelihood of containing organisms resistant to PZA, as it is estimated that in M. tuberculosis, between 1 in 107 and 1 in 1010 cells are resistant to any drug ().

Second, there is variability in the concentration of the inoculum used in the BT960 test according to the day of test setup. For days one and two after the culture flags positive, there is no dilution of the MGIT seed vial, but for days 3 to 5, the inoculum is diluted 1:5. This may lead to considerable variation in the amount of the organism in the inoculum and could cause the lack of reproducibility found during repeat testing.

Third, the inoculation method differs between the two systems. For the 460TB, a fine-needle tuberculin syringe is used, and for the BT960, the inoculum is dispensed with a disposable pipette tip, which may result in uneven distribution of bacilli due to “clumping.”

The sensitivity of the PZase assay is reported to vary between 79 and 96% (, , ). All of the discordant isolates that were tested showed the presence of PZase. Sequencing of the pncA gene that encodes PZase has shown that 74% to 97% of all PZA-resistant strains of M. tuberculosis carry a mutation in several different regions of the gene (, , ). None of the discordant strains were found to have pncA gene mutations.

These results corroborate the 460TB results as PZA susceptible and the BT960 results as falsely resistant. For laboratories which perform a large number of susceptibility tests with the BT960 system, this discordance could lead to a significant number of false resistant and major error (3) results for PZA, as well as therapeutic issues in patient management.

Due to the potential for false resistant results during PZA testing with the BT960, laboratories should consider retesting all PZA-resistant isolates with the 460TB reference method before reporting results. Since PZA is considered an essential component of first-line TB therapy, it is important that laboratories find a successful algorithm to provide rapid and accurate susceptibility results for PZA.

Footnotes

REFERENCES

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Bactec Mgit 960 Specifications

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