LABORATORY METHODS: TUBERCULOSIS DIAGNOSIS

TB CASE MANAGEMENT AND CONTACT INVESTIGATION INTENSIVE LABORATORY METHODS: TUBERCULOSIS DIAGNOSIS LEARNING OBJECTIVES Upon completion of this session, participants will be able to: 1. Describe three laboratory methods used in the diagnosis and control of TB resulting in a better understanding of laboratory results and improved communication between the clinician, the laboratory, and the patient INDEX OF MATERIALS 1. Laboratory Methods: Tuberculosis Diagnosis slide outline Presented by: Ed Desmond, Ph.D. PAGES 1-27 SUPPLEMENTAL MATERIAL None, UCSF 300 Frank H. Ogawa Plaza, Suite 520 Oakland, CA; Office (510) 238-5100

TB CASE MANAGEMENT AND CONTACT INVESTIGATION INTENSIVE ADDITIONAL REFERENCES CDC. Availability of an Assay for Detecting Mycobacterium tuberculosis, Including Rifampin- Resistant Strains, and Considerations for Its Use United States, 2013. MMWR 2013;62 (No.41) October 18, 2013. CDC. Guide to the application of genotyping to tuberculosis prevention and control. Page last updated September 1, 2012. www.cdc.gov/tb/programs/genotyping/manual.htm CDC. Report of an expert consultation on the uses of nucleic acid amplification tests for the diagnosis of tuberculosis. Page last updated September 1, 2012. www.cdc.gov/tb/publications/guidelines/amplification_tests/background.htm WHO. Drug-resistant tuberculosis. Frequently asked questions. January 2012. http://www.who.int/tb/challenges/mdr/tdrfaqs/en/# (Accessed November 10, 2014). CDC. Updated Guidelines for Using Interferon Gamma Release Assays to Detect Mycobacterium tuberculosis Infection, United States. MMWR 2010; 59 (No.RR-5) See CDC factsheet Interferon-Gamma Release Assays (IGRAs). Page last updated September 1, 2012. http://www.cdc.gov/tb/publications/factsheets/testing/igra.htm Chang-Hong, S., Xiao-Wu, W., Hai, Z., et al. Immune responses and protective efficacy of the gene vaccine expressing Ag85B and ESAT6 fusion protein from Mycobacterium tuberculosis. DNA Cell Biol. 2008 Apr;27(4):199-207. Honscha, G., Von Groll, A., Valenca, M., et al. The laboratory as a tool to qualify tuberculosis diagnosis. Int. J. Tuberc Lung Dis. 2008;12(2):218-20. Perez-Martinez, I., Ponce-De-Leon, A., Bobadilla, M., et al. A novel identification scheme for genus Mycobacterium, M.tuberculosis complex, and seven mycobacteria species of human clinical impact. Eur. J. Clin. Microbiol. Infect. Dis. 2008;27(6):451-459. Barman, P., Gadre, D., A study of phage based diagnostic technique for tuberculosis. Indian J. Tuberc. Jan. 2007; 54(1):36-40. Haldar, S., Chakravorty, S., Bhalla, M., De Majumdar, S., Tyagi, JS. Simplified detetion of Mycobacterium tuberculosis in sputum using smear microscopy and PCR with molecular beacons. J. Med. Microbiol. 2007;56(Pt.10):1356-62. Nahid, P., Pai, M., Hopewell, P. Advances in the diagnosis and treatment of tuberculosis. Proc. Am. Thorac. Soc. 2006; 3:103-110., UCSF 300 Frank H. Ogawa Plaza, Suite 520 Oakland, CA; Office (510) 238-5100

TB CASE MANAGEMENT AND CONTACT INVESTIGATION INTENSIVE Somoskovi, A., Dormandy, J., Mitsani, D., Rivenburg, J., Salfinger, M. Use of smearpositive samples to assess the PCR-based genotype MTBDR assay for rapid, direct detection of the Mycobacterium tubercuslosis complex as well as its resistance to isoniazid and rifampin. J. Clin. Microbiol. 2006;44(12):4459-4463. Lin, G., Probert, W., Lo, M., Desmond, E. Rapid detection of isoniazid and rifampin resistance mutations in Mycobacterium tuberculosis complex from cultures or smearpositive sputa by use of molecular beacons. J. Cli. Microbiol. 2004;42(5):4204-4208. Barnes, P., Cave, D. Molecular epidemiology of tuberculosis. NEJM. 2003;349(12): 1149-1155. Review article. Dowdy, D.W., Maters, A., Parrish, N., Beyer, C., Dorman, S.E. Cost-effectiveness analysis of the gen-probe amplified mycobacterium tuberculosis direct test as used routinely on smear-positive respiratory specimens. J. Clin. Microbiol. 2003;41(3):948-53. Drobniewski, F.A., Caws, M., Gibson, A., Young, D. Modern laboratory diagnosis of tuberculosis. Lancet Infect. Dis. 2003;3(3):141-47. Van Der Zanden, A.G., Te Kopppele-Vije, E.M., Vijaya Bhanu, N., et al. Use of DNA extracts from Ziehl-Neelsen-stained slides for molecular detection of rifampin resistance and spoligotyping of Mycobacterium tuberculosis. J. Clin. Microbiol. 2003;41(3):1101-08. Gillespie, S. Minireview. Evolution of drug resistance in Mycobacterium tuberculosis: clinical and molecular perspective. Antimicrob. Agents Chemother. 2002;46(2):267-274. Mostowy, S., Behr, M.A., Comparative genomics in the flight against tuberculosis: diagnostics, epidemiology and BCG vaccination. Am. J. Pharmacogenomics. 2002;2(3):189-196. Somoskovi, A., Mester, J., Hale, Y.M., Parsons, L.M., Salfinger, M. Laboratory diagnosis of nontuberculous mycobacteria. Clin. Chest Med. 2002;23(3):585-597. Breese, P.E., Burman, W.J., Hildred, M., et al. The effect of changes in laboratory practices on the rate of false-positive cultures for Mycobacterium tuberculosis. Arch Pathol. Lab Med. 2001;125(9):1213-1216. Somoskovi, A., Parsons, L.M., Salfinger, M. The molecular basis of resistance to isoniazid, rifampin, and pyrazinamide in Mycobacterium tuberculosis. Respir. Res. 2001;2(3):164-168. Hale, Y.M., Desmond, E.P., Jost, K.C., Jr., Salfinger, M. Access to newer laboratory procedures: a call for action. Int. J. Tuberc Lung Dis. 2000;4(12 suppl 2):S171-175., UCSF 300 Frank H. Ogawa Plaza, Suite 520 Oakland, CA; Office (510) 238-5100

LABORATORY METHODS: Tuberculosis Diagnosis Ed Desmond Microbial Diseases Lab, Calif. Dept. of Public Health Richmond, CA (510) 412-3781 ed.desmond@cdph.ca.gov Specimen collection and transport Specimens (sputum, bronchial washings, urine, etc.) should be collected in a laboratory-approved sterile, leak-proof, non-breakable container Containers must be labeled with patient s name and date collected Begin collecting specimens prior to initiation of therapy 1

Collection and transport (2) Sputum is the most common specimen Collect 5-10 mls of an early morning specimen, prior to eating Usually 3 specimens on 3 different days are recommended for diagnosis Collection and transport (3) Contaminated specimens can be minimized by Instructing the patient to rinse mouth with preferably sterile water before collecting the specimen Returning the specimen to the lab as soon as feasible after collection 2

Collection and transport (4) Indicate type of specimen on laboratory requisition form Keep all specimens refrigerated and transport as soon as possible to the lab How many specimens to collect? The greater the number of specimens, the higher the probability of a positive Law of diminishing returns: 4 specimens doesn t give many more positives than 3, so 3 is usual guideline 3

Sputum smear microscopy results according to the specimen collection Study Specimen Type Total % Positive 1 Overnight 160 85,0 Spot 160 51,8 2 Overnight 181 31,5 Spot 179 13,9 1 PANDE et al., Indian J Tuberc 21:1974, 192 2 R.VALLADERS & R.URBANCZIK, Instituto Nacional de TB, Venezuela 1968 1969 (not published) POSITIVITY ON SMEAR RELATED TO QUALITY OF SPUTUM SPECIMENS Group No. of specimens in each group Per cent of specimens Number positive Per cent positive Saliva 1125 32.9 21 1.8 Mucous 1707 49.9 68 3.5 Mucopurulent 583 17.2 220 37.7 Note that muco purulent specim ens are positive more often than saliva or mucous. L.POLLAK & R.URBANCZIK, Bol Inform Inst Nac Tuberc (Caracas) 2:1969,5-8 4

Processing pulmonary specimens Digestion and decontamination Pulmonary specimens are exposed to a mucolytic agent to dissolve mucin and liquefy the specimen N-acetyl-L-cysteine (NALC) is the most common mucolytic agent used Processing pulmonary specimens (2) Digestion and decontamination Specimens are also treated with a liquid decontaminant, generally sodium hydroxide, a strong alkali which is more toxic to oral flora than AFB Material is concentrated by centrifugation 5

Staining concentrated smear Fluorochrome stains Fluorochrome stained smears require a fluorescent microscope Generally read at 250X-450X magnification which allows rapid scanning of the smear Auramine-rhodamine is an example of such a stain where the AFB appear yellow against a black background 6

Staining concentrated smear (2) Carbol fuchsin-based stains Utilize a regular light microscope Must be read at a higher magnification Two types: Ziehl-Neelsen and Kinyoun. Both use carbol fuchsin/phenol as the primary dye (NOTE: ZN is more sensitive) Smear is then decolorized with acid-(hci) alcohol and counter-stained with methylene blue From CDC Lab Manual 7

REPORTING AFB SMEAR RESULTS* Number of AFB found: Report: 0 or Neg 1-2 / 300 fields 1-9 / 100 fields 1+ 1-9 / 10 fields 2+ 1-9 / field 3+ >9 / field 4+ *CDC System (WHO system goes up to 3+ only) Inoculating growth media for culture Solid media Two types most commonly used are Lowenstein-Jensen which is egg-based Middlebrook 7H 10 or 7H11 which are agarbased 8

Inoculating growth media for culture (2) Solid media have the advantage that organisms (colonies) can be seen on the surface of the medium If there is mixed growth or contamination, picking individual colonies can allow you to obtain a pure culture. 9

M. tb on egg medium From CDC Lab Manual Inoculating growth media for culture (3) Liquid media Liquid or broth medium has the advantage of allowing detection of AFB more quickly Drug susceptibility testing using growth in liquid media leads to more rapid reporting of results Examples of liquid media are Trek and MGIT systems 10

MGIT Incubator 11

Accuracy problems in the TB lab False positive results, due to: o Cross-contamination during specimen processing o Specimen mix-up or mislabeling Inadequate primary culture media (some labs use only solid media) Inaccurate drug susceptibility results due to inadequate quality control 12

Identification of acid-fast bacilli (AFB) Growth characteristics (preliminary ID) Preliminary indication of M. tb can be made from macroscopic & microscopic observation) Rate of growth Colonial morphology Pigmentation 13

Colonial Morphology (1) Smooth colonies on 7H-10 medium 14

Colonial Morphology (2) Rough colony on 7H-10 medium Identification of acid-fast bacilli (AFB) (2) Biochemical tests: not used now because too slow There is a battery of 8-12 biochemical tests used to differentiate within the mycobacterium genus Nitrate reduction and niacin accumulation are definitive for M. tb 15

Identification of acid-fast bacilli (AFB) (3) Nucleic acid probe tests (non-amplified) DNA probe tests are species or complex specific Require less time than biochemical tests for identification Commercial probes are available for M. tb complex, MAC, M. kansasii and M. gordonae Identification of acid-fast bacilli (AFB) (4) High performance liquid chromatography (HPLC) HPLC uses a chromatography method to identify mycobacteria based on their mycolic acid profiles (cell wall composition) Instrument is expensive/usually reserved for larger laboratories MALDI-TOF (matrix assisted laser desorption ionization-time of flight) is now more widely used than HPLC Like HPLC, expensive instrument, but quicker 16

Susceptibility testing of M. tuberculosis When to test All primary M. tb isolates from patients should be tested In addition, test isolates from relapse or re-treatment cases Test when drug resistance is suspected Susceptibility testing of M. tuberculosis (2) Methods for susceptibility testing Agar proportion method compares growth on agar media with and without one of the four primary drugs Broth based (MGIT, Trek) Requires inoculation of the strain in broth with each of the (5) primary drugs, plus control vial Growth of the strain in a vial with a drug indicates resistance to that drug 17

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Direct detection of M. tuberculosis in clinical material Several commercial nucleic acid amplification tests (NAAT) for M. tb are now available, including Gen-Probe Amplified Mycobacterium Tuberculosis Direct (AMTD) (for smear + or smear -) Cepheid GeneXpert (now has FDA clearance) These tests are designed to amplify and detect DNA specific to M. tb The sensitivity of these methods allows for direct detection of M. tb in clinical specimens Uses of NAAT for Direct Detection of MTBC in Respiratory Specimens (NAAT = nucleic acid amplification test) CDC guidelines recommend as standard of practice Will allow quicker diagnosis in some smear neg patients Only if patients are true TB suspects Only for untreated patients Not necessary to test smear positives when classic TB symptoms and history are present Do test smear negatives when clinical suspicion of TB is moderate or high 19

More encouragement to use NAAT Pascopella (2004) J. Clin. Microbiol 42:4209 For smear neg patients, health care providers often/typically don t start Rx until culture is + Results in a delay in initiation of Rx, typically 3 weeks NAA would detect many of these patients, earlier initiation of Rx MMWR guidelines: Jan. 16, 2009 58(1):7-10 Genotyping methods Spoligotyping (spacer oligonucleotide typing) MIRU/VNTR (mycobacterial interspersed repetitive units/ variable number of tandem repeats) RFLP fingerprinting (restriction fragment length polymorphism) Whole genome sequencing (WGS) 20

Spoligotyping summary Gives a result as a number, so to tell if 2 strains are different, just see if they have different numbers Not too powerful at discriminating different strains. Sometimes strains that are not part of the same outbreak will have the same spoligotype e.g., Manila strain & Beijing strain Is now performed at CDC, using DNA sequencer MIRU summary A PCR-based method, like spoligotyping Like spoligotyping, the result is a number (24 digits) Uses a DNA sequencer instrument to analyze the PCR products Like spoligotyping, MIRU sometimes doesn t discriminate between unrelated strains Since April 2009, a new 24 locus MIRU protocol is in use, making it more powerfully discriminatory 21

Using MIRU and spoligotyping together Both are PCR-based strain typing methods, so you can do them with just a small amount of DNA If 2 strains of M. tuberculosis are different from one another, it is unlikely that they will have the same spoligotype and the same MIRU type Possible exceptions include Manila strains and Chinese Beijing strains Universal genotyping approach (at Michigan lab) All isolates MIRU-VNTR Whole genome sequencing with Spoligotype inferred From sequence 2 weeks Additional 3 weeks 22

Genotyping: Uses 1. Cross contamination studies 2. Outbreak investigation 3. TB Control needs, such as identifying settings where transmission occurs Note: when genotyping links patients in a cluster, but no epi links are found, whole genome sequencing may be helpful in identifying which patients are truly linked in the same chain of transmission Contact info for (Michigan) genotyping laboratory James T. Rudrik, Ph.D. Office: 517-335-9641 Fax: 517-335-9631 rudrikj@michigan.gov Angie Schooley, B.S. schooleya@michigan.gov Office: 517-335-9637 Fax: 517-335-9631 927 Terminal Drive Lansing, MI 48906 Please note that cultures for genotyping are sent through the county public health laboratory. 23

Molecular Detection of Drug Resistance: Resistance Mutations GeneXpert & Pyrosequencing Principles of Molecular Detection of Drug Resistance GeneXpert uses molecular beacon probes in an automated, user friendly (expensive) system With molecular beacons: if normal susceptible gene targets are present, molecular beacon will hybridize and light up Absence of molecular beacon signal suggests drug resistance For sequencing (e.g. pyrosequencing), the actual gene sequence is determined Actual sequence is more informative 24

Limitations of molecular detection of drug resistance The predictive value of a negative result for INH (no mutations found) is in the low 90s (about 93%) to date. Pyrosequencing or GeneXpert can be used to guide treatment until conventional drug susceptibility results are available (usually about a month later). Detection of a mutation in rpob gene by GeneXpert doesn t always mean rifampin resistance Some rpob mutations don t cause rif resistance When GeneXpert detects a mutation, follow-up DNA sequencing should be done to confirm rifampin resistance. Molecular testing should be followed by culture-based DST Detection of Drug Resistance Mutations Drugs of interest: For XDR screening INH, RIF, KAN, AMK, CAP, fqs Targeted Genes for pyrosequencing katg, inha promoter, ahpc, fabg for INH rpob for RIF rrs for KAN, AMK & CAP gyra for Quinolones GeneXpert detects resistance to rifampin only G Lin PSQ 11-2-10 49 25

Comparison of MB & PSQ Report Interpretation of silent mutations or mutations not conferring R GeneXpert MB Mutation present or not Misinterpret as R PSQ Exact SQ Does not misinterpret Hands-on time 1.5 hr, simple 2.5 hr, more steps Total test time 2.5 hr 5 hr G Lin PSQ 11-2-10 50 Advantages of PSQ over MB Results show sequences. You would know what mutations are if present. More information provided and less ambiguity. Silent mutations do not lead to wrong interpretation. Mutations not conferring resistance do not lead to wrong interpretation. Difficult targets may still be sequenced. At present, GeneXpert detects resistance to rifampin only. 51 26

Suggestion for requesting molecular detection of drug resistance Acid-fast smear-positive specimen Some of the specimen sediment is available for sending to reference lab (State Microbial Diseases Lab or CDC) Drug resistance is suspected, or A susceptible population has been exposed, or The culture is mixed or non-viable, so regular drug suscept. testing can t be done CDC also has Molecular Detection of Drug Resistance (MDDR) program: tests for mutations associated with resistance to additional drugs ethambutol, pyrazinamide Thank you 27