Understand the principles of bacterial diagnostics
Manifestations of infection
host <-> microorganism interaction
virulence factors + host health
signs and symptoms dep. on body site and severity of infection
microbial causes of infection
exogenous vs endogenous
specimen selection, collection and processing
signs and symptoms as hints
collection of specific sample acc. to hypothetical specimen before any drug application
specimen amount + transport influencing lab results
microbiologic examination
direct + indirect methods
Provide details on the German public health network
Robert Koch Institute = government’s central biomedicine institute
-> identification, surveillance and prevention of (infectious) diseases via epidemiological and medical analyses
-> information provider and advisor of health-related political decision-making, scientific sector and general public
-> special laws for execution of tasks
-> federal health reporting (e. g. to WHO)
consulting laboratories: guidance and advice for specific pathogen
national reference centers: accurate diagnosis, resistance testing, prevention of spread, verification of tests from other labs, production and distribution of reference materials for external quality control and quality assurance
How do we classify pathogenic bacteria?
unlikely to cause human disease (E. coli K12)
human disease, probably hazard to employees, unlikely to spread, effective prophylaxis/treatment available (Burkholderia cepacia, Campylobacter jejuni, Corynebacterium diphtheriae, E. coli)
severe human disease, probably serious hazard to employees, may spread, usually effective prophylaxis/treatment available (Bacillus anthracis, E. coli O157, Mycobacterium tuberculosis)
severe human disease, serious hazard to employees, likely to spread, no effective prophylaxis/treatment available (Herpesvirus simiae, Ebola, Marburg virus, Congo haemorrhagic fever virus)
Describe how selective/differential agar can be used to grow different bacterial pathogens
broth
enrichment facilitates pathogenic growth of slow growing organisms in (low in volume) samples
-> Mycobacterium tuberculosis, Haemophilus spp., Neisseria spp.
differential media
specific dyes for quick identification due to characteristic colouring
chromogenic agar
incooperation of multiple substrate-chromogen combinations w. careful interpretation due to eyeballing colouring (expensive)
blood agar
rich, non-selective media for isolation of a range of fastidious bacteria
-> Streptococcus pneumoniae, Neisseria meningitidis, Staphylococcus aureus, Clostridioides difficile, Proteus spp.
Understand why AMR profiles need to be determined and the different phenotypic methods used for profiling antimicrobial susceptibilities (MICs, gradient method, and disk diffusion test)
growth inhibition of bacteria w. most effective drugs
MIC (Minimum Inhibitory Concentration)
determination of lowest concentration of antimicrobial agent needed -> quantitative
serial dilutions in grids + inoculum into microdilution plate in series after preparation of colonies -> no color: growth inhibited
Gradient diffusion method
test strips w. antimicrobial agents into agar medium -> reading of concentration scale to determine susceptibility (Etest)
correlated well w. MIC, but some systematic biases toward higher/lower MICs
Disk diffusion test
similar to Gradiend diffusion method except using filter paper instead of test strips
no accurate quantification of minimum antimicrobial concentration, no reliable results in combination w. some antibiotic/organism combinations
Automated MIC systems
standardised w. suceptibility test results in short period of time
detection of subtle changes in bacterial growth
Provide details on immune-based diagnostic tests (ELISA, ELI-Spots) and their limitations
detection of bacterial antigens and antibodies
only for specific bacterial infections
Legionella, Mycoplasma, Chlamydiae, Rickettsia, Borrelia
no clearly identified epitopes possible
specific IgMs only in acute phase of infection
indirect ELISA
detection of antibody for pathogen
find low-level infections
-> Borrelia burgdorferi, Treponema pallidum (Syphilis)
ELI-Spot (Enzyme-Linked Immuno Spot assay)
looking for antibodies, measuring immune molecules and immune cells -> T-cell reaction against specific antigen w. colouring
-> chronic/recent Borrelia burgdorferi, Chlamydia pneuomonia, Chlamydia trachomatis, Yersinia species
Understand how PCR is used in routine diagnostics
PCR
identification of pathogenic bacteria through 16S rRNA
rapid diagnose infections via
‘unique’ genes
high sensitivity and specificity
easy
rapid
provide further details on specific tests and what species the mPCR may be used to diagnose
mPCR (multiplex PCR)
for small amounts of sample
simultaneous amplification of multiple regions w. different primer pairs
-> cost + time beneficial, exact diagnosis (sensitivity and specificity)
-> reduced no. of separate reactions
STIs primarily
Chlamydia trachomatis
Neisseria gonorrhoeae
Treponema pallidum
Trichomonas vaginalis
Mycoplasma genitalium
Ureaplasma urealyticum
Haemophilus ducrey
limit: non-specific products - interference of primer-primer interactions w. amplification => decreased sensitivity + selectivity
provide further details on specific tests and what species the LAMP-PCR may be used to diagnose
LAMP-PCR (Loop-mediated isothermal amplification)
recognision of distinct regions of target DNA -> subsequent rounds of amplification of those via loop structure
-> increase of detection limits, efficiencyt, selectivity and specificity
chorioaminonitis + premature labor
Ureaplasma parvum
Ureaplasma urealyticu
provide further details on specific tests and what species the RT-PCR may be used to diagnose
RT-PCR (Real-time PCR/qPCR)
gold standard for detection and quantification
avoiding cross contamination due to no further manipulation
wide dynamic range for quantification
determination of presence of specific genes and allels
-> strand and isolates typing, AMR profiling, toxin production
potential bioterrorism used pathogenic bacteria
Bacillus
Brucella
Burkholderia
Coxiella
Francisella
Yersinia
provide further details on specific tests and what species the dPCR may be used to diagnose
dPCR (digital PCR)
direct quantification and clonally amplification of nucleic acids strains
widely used for low-abundance nucleic acid detection + diagnosis of infectious diseases
Preparation -> Partitioning -> Amplification -> Analysis
provide further details on specific tests and what species the ddPCR may be used to diagnose
ddPCR (droplet digital PCR)
method of dPCR
good sensitivity for low-abundance DNA
variety of infections (stage dependent)
direct count of no. of bacteria
Borrelia burgdorferi
Staphylococcus
Salmonella
Listeria
Mycobacterium tuberculosis
Describe the basic background of FISH and how this might be used to diagnose bacterial infections
identification of bacterial pathogens at genus/species level
spatial resolution, morphology information in mixed species samples
biopsie or blood samples
Be able to discuss the advantages and disadvantages of molecular tests for AMR and provide examples
advantages of AMR
disadvantages of AMR
detection of resistance-coding genes /-associated mutations in DNA
detection only of known resistance genes / mutations
much faster results than phenotypic methods (e.g. crutial in clinical settings)
not always correlation btw. molecular and phenotypic test results
-> FN results due to not testing for resistance responsible gene, mutation affecting binding of primer, new, yet uncharacterised resistance mechanism
FP due to DNA contamination
Understand the background of using next generation sequencing for infection diagnostics with a focus on metagenomics and NEC
powerful
direct incooperation of WGS in routine lab workflow
typing
presence of AMR genes
genes associated w. virulence and pathogenicity
culture-free identification in complex polymicrobial samples
Metagenomics - Nanopore MinION
portable, real-time DNA analysis for in-field, clinical deployment
confident identification of
microbes to species level for accurate diagnosis
abundance within microbiota
AMR profiles
NEC (preterm infant necrotising enterocolitis) - difficult diagnosis in early stage, associated w. sudden serious deterioration
Clostridium spp.
E. colit
Enterobacter spp.
Klebsiella spp.
MR/MAR
Provide details on POCTs
POCTs biosensors (Point of care tests)
rapid detection + quantification of specific analytes by biorecognition elements (colorimetric/fluorimetric/electrochemical)
how they can be used in the context of diagnosing of bacterial infections with examples of immune/antibody based POCTs
immune/AB based
LFIAs (Lateral Flow Immuno Assays)
several for bacterial infections
Myobacterium tuberculosis
multiplex for cystic fibrosis-associated ones - Pseudomonas aeruginosa, Staphylococcus aureus)
10 endemic food-born pathogens - E. coli 0157:H7 , Parathyphi, Salmonella Typhi, Salmonella enteritidis, Vibrio cholerae O1/O139
how they can be used in the context of diagnosing of bacterial infections with examples of nucleic acid-based POCTs
nucleic acid-based
often PCR based
integration of multiple steps involved in bacterial detection onto a single chip
multiple uses w. detection of specific bacteria and genes incl. toxins and AMR
expensive, less/no flexibility
Clostridioides difficle
how they can be used in the context of diagnosing of bacterial infections with examples of protein and glycan-based POCTs
protein and glycan-based
reduction of unnecessary antibiotics treatment due to detection of microbial antigens
Staphylococcus aureus
alternative use of host biomarkers for distinguishment btw. classes of infecting microbes
Describe how mass spectrometry methods are used in diagnostics (also referring back to the Identification lecture) and how new methods such as REIMS may be used in the clinical microbiology lab
MALDI-TOF-MS for routine identification of microbial pathogens
advantage: direct identification from colonies grown on culture plates (less time consuming preparations needed)
enhanced reliability and accuracy
exploration of new perspectives
direct identification from positive blood cultures
sub-species typing
detection of drug resistance determinants
REIMS (Rapid evaporative ionization mass spectrometry
quick and accuracte speciate bacterial due to species-specific liquid profile
devlopment of customised platform for automation and high-throughput REIMS analysis
iknife
Zuletzt geändertvor 2 Jahren