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Title: Bacteremia, Fungemia, and Blood Cultures


1
Bacteremia, Fungemia, and Blood Cultures
  • Dr. John R. Warren
  • Department of Pathology
  • Northwestern University
  • Feinberg School of Medicine
  • June 2007

2
Essential Elements of Blood Cultures
  • Pathophysiology of bacteremia and fungemia
  • Microbiology of bacteremia and fungemia
  • Determinants of mortality in bacteremia and
    fungemia
  • Clinical signs and symptoms of septicemia
    (predictors)

3
Essential Elements of Blood Cultures
  • Technical variables in the collection of blood
    cultures
  • Incubation conditions
  • Blood culture systems
  • Quality management monitors

4
Pathophysiology of Bacteremia and Fungemia
  • Bacteria and fungi normally cleared from blood by
    the mononuclear phagocyte system (MPS)
    (reticuloendothelial system)
  • If entry of bacteria or fungi into the
    circulation exceeds MPS clearance capacity,
    bacteremia or fungemia results

5
Pathophysiology of Bacteremia and Fungemia
  • Encapsulated bacteria and yeast poorly cleared
    from the circulation by fixed macrophages of the
    MPS (parasite factor) especially in the absence
    of opsonizing antibody (host factor)
  • Diminished numbers of neutrophils impedes ability
    of the host to contain encapsulated bacteria and
    yeast at sites of tissue infection

6
Pathophysiology of Bacteremia and Fungemia
  • Bacteremia or fungemia represents a failure of
    host defenses to localize an infection at its
    primary tissue site
  • Bacteremia or fungemia also reflects a failure of
    a physician to remove, drain, or otherwise
    sterilize sites of infection
  • Clinical patterns of bacteremia or fungemia
    transient, intermittent, and continuous

7
Pathophysiology of Bacteremia and Fungemia
  • Transient bacteremia or fungemia lasts minutes to
    a few hours, is the most common type, and occurs
    after manipulation of infected tissue (abscesses,
    furuncles, cellulitis), instrumentation of
    colonized mucosal surfaces (dental procedures,
    cystoscopy, sigmoidoscopy), and surgery in
    contaminated areas (prostate resection,
    debridement of infected burns, vaginal
    hyterectomy), reflecting release of organisms
    into the circulation secondary to tissue trauma
    resulting from medical procedures

8
Pathophysiology of Bacteremia and Fungemia
  • Transient bacteremia or fungemia also occurs
    early in acute bacterial infection including
    pneumonia, meningitis, septic arthritis, and
    hematogenous osteomyelitis, reflecting release of
    organisms through lymphatics draining infected
    tissue into the circulation
  • Intermittent bacteremia or fungemia occurs,
    clears, then recurs with the same organism, and
    develops with undrained closed-space abscesses
    (intra-abdominal, pelvic, perinephric, hepatic,
    prostatic), and also focal infections that fail
    to resolve (pneumonia, osteomyelitis),
    reflecting irregular cycles of release into and
    clearance from the circulation of organisms
    infecting tissue

9
Pathophysiology of Bacteremia and Fungemia
  • Continuous bacteremia or fungemia is a cardinal
    feature of endocarditis and other types of
    endovascular infections (suppurative
    thrombophlebitis, infected aneurysms), reflecting
    continuous shedding of organims from endovascular
    foci into the circulation
  • Continuous bacteremia also occurs early (initial
    few weeks) in typhoid fever and brucellosis

10
Microbiology of Bacteremia and Fungemia
  • Etiological Significance of Gram-Negative
    Bacteria
  • Escherichia coli 142/143 (99.3)
  • Klebsiella pneumoniae 65/65 (100)
  • Enterobacter cloacae 25/25 (100)
  • Serratia marcescens 22/22 (100)
  • Proteus mirabilis 16/16 (100)
  • Other Enterobacteriaceae 41/45 (91)
  • Pseudomonas aeruginosa 53/55 (96)
  • Acinetobacter baumannii 13/16 (81)
  • Stenotrophomonas maltophilia 5/7 (71)
  • Weinstein et al, 1997

11
Microbiology of Bacteremia and Fungemia
  • Etiological Significance of Gram-Positive
    Bacteria
  • Staphylococcus aureus 178/204 (87)
  • Coagulase T Staphylococcus 87/703 (12)
  • Streptococcus pneumoniae 34/34 (100)
  • Group A Streptococcus 3/3 (100)
  • Group B Streptococcus 10/15 (67)
  • Enterococcus 65/93 (70)
  • Viridans streptococci 27/71 (38)
  • Bacillus 1/12 (8)
  • Corynebacterium 1/53 (2)
  • Lactobacillus 6/11 (55)
  • Weinstein et al., 1997

12
Microbiology of Bacteremia and Fungemia
  • Etiological Significance of Anaerobic Bacteria
  • Bacteroides fragilis group 16/18 (89)
  • Other gram-negatives 2/5 (40)
  • Clostridium perfringens 3/13 (23)
  • Clostridium species 12/15 (80)
  • Propionibacterium 0/48 (0)
  • Other gram-positives 4/7 (57)
  • Weinstein et al., 1997

13
Microbiology of Bacteremia and Fungemia
  • Etiological Significance of Yeast
  • Candida albicans 27/30 (90)
  • Candida glabrata 14/15 (93)
  • Other Candida species 15/15 (100)
  • Cryptococcus neoformans 8/8 (100)
  • Weinstein et al., 1997

14
Microbiology of Bacteremia and Fungemia
  • Blood Culture Contaminants1
  • Propionibacterium (0)
  • Corynebacterium (2)
  • Bacillus (8)
  • Coagulase-negative Staphylococcus (12)
  • Viridans streptococci2 (38)
  • 1In order of decreasing probability of being a
    contaminant of blood isolates considered
    etiological in parentheses (Weinstein et al.,
    1997)
  • 2Excluding Streptococcus pneumoniae

15
Microbiology of Bacteremia and Fungemia
  • Association of Organisms with Neutropenia1
  • lt1,000 gt1,000
  • S. aureus 9 (6) 169 (21)
  • Yeasts 17 (12) 48 (6)
  • Polymicrobial 24 (30) 55 (13)
  • 1No. () of blood culture isolates from patients
    with indicated neutrophil count. Only
    differences statistically significant (plt.05) by
    ?2 are included (Weinstein et al., 1997).

16
Microbiology of Bacteremia and Fungemia
  • Association of Organisms with Shock1
  • Hypotensive Normotensive
  • Polymicrobial2 16 (14) 63 (9)
  • 1No. () of blood culture isolates from
    hypotensive and normotensive patients (Weinstein
    et al., 1977).
  • 2plt.05 (?2). Significant differences not
    observed with individual organisms, nor for
    unimicrobial bacteremia and fungemia.

17
Microbiology of Bacteremia and Fungemia
  • Sources of Bacteremia and Fungemia
  • No. of episodes of total episodes1
  • Unknown 216 26
  • Vascular Catheter 161 19
  • Genitourinary Tract 147 18
  • Respiratory Tract 104 12
  • Abdominal2 102 12
  • Other3 113 13
  • 1Total no. of episodes 843 (Weinstein et al.,
    1997) in which source confirmed by culture and/or
    clinical evidence
  • 2Bowel and peritoneum, biliary tract,
    intra-abdominal abscess
  • 3Skin, bone and joint, surgical wound, and other

18
Microbiology of Bacteremia and Fungemia
  • Sources of Gram-Positive Bacteremia1
  • Source No. () of Episodes2
  • S. aureus (159) IV56 (35)
  • Skin19 (12)
  • Respiratory18 (11)
  • Bone/joint10 (6)
  • Coagulase T Staph (73) IV59 (81)
  • Skin5 (7)
  • Strep. pneumoniae (34) Respiratory26 (76)
  • Enterococcus (38) GU15 (39)
  • IV3 (8)
  • 1Numbers in parentheses indicate bacteremic
    episodes for each organism. Weinstein et al.,
    1997
  • 2() of the indicated source for the organism

19
Microbiology of Bacteremia and Fungemia
  • Sources of Bacteremia due to Enterobacteriaceae1
  • Source No. () of Episodes2
  • E. coli (116) GU67 (58)
  • Biliary11 (9)
  • Peritoneal10 (9)
  • K. pneumoniae (48) Biliary10 (21)
  • GU8 (17)
  • Peritoneal5 (10)
  • S. marcescens (20) GU4 (20)
  • Respiratory4 (20)
  • IV3 (15)
  • Prot. mirabilis (13) GU9 (69)
  • 1Numbers in parentheses indicate bacteremic
    episodes for each organism. Weinstein et al.,
    1997
  • 2() of the indicated source for the organism

20
Microbiology of Bacteremia and Fungemia
  • Sources due to Gram-Negative Non-Fermenters and
    Yeast1
  • Source No. () of
    Episodes2
  • P. aeruginosa (48) Respiratory19 (40)
  • GU9 (19)
  • A. baumannii (12) Respiratory3 (25)
  • C. albicans (21) IV5 (24)
  • Peritoneal2 (10)
  • C. glabrata (12) GU4 (33)
  • 1Numbers in parentheses indicate bacteremic or
    fungemic episodes for each organism. Weinstein
    et al., 1997
  • 2() of the indicated source for the organism

21
Microbiology of Bacteremia and Fungemia
  • No. () deaths/ Relative risk
  • No. episodes of death
  • Yeast 19/53 (36) 6.54
  • Polymicrobial 27/79 (34) 2.16
  • Enterobacteriaceae2 31/125 (25) 4.53
  • S. pneumoniae 6/34 (18) 3.22
  • P. aeruginosa 8/48 (17) 3.04
  • Unimicrobial 120/764 (16) 1.00
  • Enterococccus 5/38 (13) 2.40
  • E. coli 14/116 (12) 2.20
  • Staph. aureus 19/159 (12) 2.18
  • CoagT Staph. 4/73 (6) 1.00
  • 1Associated mortality for individual organisms in
    unimicrobial bacteremia or fungemia, and
    unimicrobial vs. polymicrobial bacteremia.
    Weinstein et al, 1997
  • 2Enterobacteriaceae other than E. coli

22
Microbiology of Bacteremia and Fungemia
  • No. () deaths/ No. episodes1
  • Hypotensive Normotensive
  • Staph. aureus 5/18 (28) 14/141 (10)
  • E. coli 4/13 (31) 10/103 (10)
  • Enterobac. (other) 12/23 (52) 19/104 (18)
  • P. aeruginosa 3/6 (50) 5/42 (12)
  • Yeast 5/7 (71) 14/46 (30)
  • Unimicrobial 35/96 (36) 85/668 (13)
  • Polymicrobial 10/16 (63) 17/63 (27)
  • 1Only differences statistically significant
    (plt.05) by ?2 are included (Weinstein et al.,
    1997). No significant differences in mortality
    were observed for coagulase-negative
    staphylococci, S. pneumoniae, other streptococci,
    Enterococcus, other gram-negative non-fermenters,
    and anaerobic bacteria.

23
Determinants of Mortality in Bacteremia and
Fungemia
  • Multivariate Relative Risk
  • of Death (lt.05, Weinstein et al, 1997)
  • Respiratory tract, 2.86
  • bowel, peritoneum,
  • or unknown source
  • Inappropriate antibiotic 2.72
  • treatment
  • Hypotension 2.29
  • Enterobacteriaceae and 2.27
  • yeast
  • Absence of fever 2.04
  • Malignancy, AIDS, or 1.98
  • renal failure
  • Age (gt70 years) 1.80

24
Clinical Indicators of True Bacteremia or
Fungemia1
  • Peripheral leukocyte count gt20,000 or lt4,000
  • Neutropenia (neutrophil count lt 1,000)
  • Hypotension
  • Hypothermia (lt36oC) or hyperthermia (gt40oC)
  • 1At the time of first positive blood culture
    (Weinstein et al., 1997)

25
Clinical Manifestations of Bacteremia
  • Significant Independent Multivariate Predictors
    of Positive Blood Culture Results1
  • Variable OR (95 CI) P2
  • Temp gt37.8oC 2.42 (1.41-4.14) .001
  • WBC gt12,000 2.40 (1.41-4.10) .001
  • Hospital gt10 d 2.02 (1.25-3.24) .004
  • Age gt30 y 2.07 (1.19-3.60) .010
  • Heart rate gt90 1.90 (1.13-3.17) .015
  • Central venous lines 1.89 (1.02-3.50) .043
  • 1Jaimes et al, 2004 n89 patients with positive
    blood cultures, and n411 patients with negative
    cultures
  • 2Likelihood ratio statistic

26
Clinical Manifestations of Bacteremia
  • Insignificant Predictors of Positive Blood
    Culture Results1
  • Variable Negative Positive
    P2
  • Comorbities2 159 (38.7) 32 (36)
    .630
  • Chills 43 (10.4) 9 (10)
    .769
  • Antibiotic use 210 (51.1) 45 (50.6)
    .785
  • 1No. () of patients with negative blood cultures
    (n411) and positive blood cultures (n89)
    subjected to univariate analysis for each
    variable by Students t test (Jaimes et al.,
    2004)
  • 2HIV infection, chronic renal failure, diabetes
    mellitus, immunosupressive chemotherapy, systemic
    cortico-steroid, and malignant disease

27
Technical Variables in the Collection of Blood
Cultures
  • Skin antisepsis
  • Volume of blood
  • Ratio of blood to broth
  • Number of blood cultures
  • Sites of blood collection
  • Blood culture sets

28
Skin antisepsis
  • Preparation of skin with an agent bactericidal
    for surface bacterial commensals
  • Commensals (especially coagulase-negative
    staphylococci) residing deep within sebaceous
    glands evade the bactericidal action of skin
    preparation agents
  • Preparation agents include povidone-iodine (skin
    contact killing time of 1.5-2 min), tincture of
    iodine (contact killing time of 0.5 min), and
    recently chlorhexidine (ChloraPrep) (NMH
    application to skin venepuncture site for 30 sec
    by back and forth friction scrub, followed by 30
    sec drying time)
  • Blood culture contamination rate reflects
    effectiveness of antisepsis with lowest rates
    obtained by laboratory phlebotomy teams

29
Volume of blood
  • Bloodstream infections frequently caused by
    relative few organisms in a given volume of blood
    (lt1- 10 colony forming units/mL of blood)
  • Sensitivity of blood cultures thus directly
    proportional to the volume of blood cultured
  • Optimal volume for adults 20-30 mL of blood per
    culture set
  • Blood volumes gt30 mL do not enhance the
    sensitivity of blood cultures for adults and
    contribute to nosocomial anemia
  • Optimal volume for children (birth-15 y) 4 to
    4.5 of patients total blood volume (Kellogg et
    al., JCM 382181-2185, 2000)

30
Ratio of blood to broth
  • Balance between dilutional effect of broth on
    antibiotics, complement, lysozyme, and phagocytic
    white cells on the one hand and inadequate volume
    of blood on the other
  • Optimal dilution of blood to broth is 15 to 110
    (v/v)

31
Number of blood cultures
  • Collection of multiple blood culture sets at
    different venipuncture sites
  • Contamination by skin organism or environmental
    spores indicated if only one of multiple sets
    positive for coagulase-negative Staphylococcus,
    Bacillus, Corynebacterium, viridans streptococci,
    or Propionibacterium.
  • Acute febrile episode 2 sets from separate sites
    within 10 minutes before antimicrobial
  • Nonacute disease 2 or 3 sets from separate sites
    at gt 3 hr intervals within 24 hr before
    antimicrobial
  • Acute endocarditis 3 sets from separate sites
    within 1-2 hr before antimicrobial
  • Subacute endocarditis 3 sets from separate sites
    at gt1 hr intervals within 24 hr if these sets
    culture negative obtain 2-3 additional sets
  • Fever of unknown origin 2 or 3 sets from
    separate sites at gt1 hr intervals within 24 hr
    if these sets culture negative, obtain 2-3
    additional sets

32
Optimal Testing Parameters for Blood Cultures1
  • 37,568 blood cultures tested with automated
    BACTEC 9240 instrument at Mayo Medical Center
    June 1996-October 1997
  • 20 mL blood inoculated in equal volumes to two
    culture bottles, first to BACTEC Plus Aerobic/F
    resin bottle, and then to BACTEC Lytic/10
    Anaerobic bottle
  • 20 mL blood obtained separately for a total of 40
    mL within 30 min
  • Blood cultures incubated 7 days on BACTEC 9240
    instrument
  • 1Cockerill, III et al., Clin Inf Dis
    381724-1730, 2004

33
Optimal Testing Parameters for Blood Cultures1
  • No. pathogens recovered
  • 10 mL 20 mL 30 mL 40 mL
  • S2 235 3053 3464 3715
  • EC2 13 14 14 14
  • 1Cockerill, III et al., Clin Inf Dis
    381724-1730, 2004
  • 2S sepsis without endocarditis, E
    endocarditis
  • 320 mL vs. 10 mL 29.8 increase in yield
  • 430 mL vs. 20 mL 13.4 increase in yield
  • 540 mL vs. 30 mL 7.2 increase in yield

34
Optimal Testing Parameters for Blood Cultures1,2
  • Cons 1st 1st 1st 1st
  • Cult3 gt1 gt2 gt3 gt4
  • 615(81) 497(77)
    106(65) 62(61)
  • 116(15) 116(18)
    25(15) 17(17)
  • 3 25(3) 25(4) 25(15)
    15(15)
  • 4 7(1) 7(1) 7(5)
    7(7)
  • 5 - - - -
  • - - - -
  • 1Cockerill, III et al., Clin Inf Dis
    381724-1730, 2004.
  • 2Pathogen recovery without endocarditis (n763)
    1st bottle
  • indicated for patients with 1 or more, 2 or
    more, 3 or more, and 4
  • or more (up to 6) collected.
  • 3Consecutive blood culture drawn 1 culture
    (n118), 2 cultures (n482), 3
  • cultures (n62), 4 cultures (n98), 5 cultures
    (n0), and 6 cultures (n3)
  • drawn for the indicated number of patients.

35
Optimal Testing Parameters for Blood Cultures1
  • 1st 1st 1st 1st
  • gt1 gt2 gt3 gt4
  • 37(93) 31(91) 16(89)
    9(82)
  • 2(5) 2(6) 1(6)
    1(9)
  • 3 0 0 0 0
  • 4 1(3) 1(3) 1(6) 1(9)
  • 5 - - - -
  • - - - -
  • 1Cockerill, III et al., Clin Inf Dis
    381724-1730, 2004
  • 2Pathogen recovery with endocarditis (n40) and
    consecutive
  • blood cultures (1-6) over 24 hours. 1st bottle
    indicated for
  • patients with 1, 2, 3, or 4 or more bottles (up
    to 6) collected.

36
Optimal Testing Parameters for Blood Cultures1
  • Twenty mL of blood inoculated in equal volumes to
    an aerobic and anaerobic broth bottle (one blood
    culture set)
  • Second blood culture set inoculated immediately
    after the first from a different venipuncture
    site
  • Two additional blood culture sets inoculated over
    remaining 24 hr if sepsis persist
  • 1Cockerill, III et al., Clin Inf Dis
    381724-1730, 2004

37
Sites of blood collection
  • Venipuncture at separate skin sites method of
    choice
  • Blood should not be obtained from an indwelling
    intravenous or intra-arterial catheter unless
    catheter-related infection suspected, or skin
    venipuncture sites not available
  • For the evaluation of catheter-associated
    bloodstream infection, a concomitantly drawn
    venipuncture specimen should be paired with a
    catheter specimen

38
Blood culture sets
  • Two aerobic bottles versus a pair of aerobic and
    anaerobic bottles (?) (Decreased frequency of
    anaerobic bacteremia)
  • Three bottle versus two bottle sets (?)
    (Increased sensitivity of automated continuously
    monitoring blood culture instruments)

39
Incubation conditions
  • Without EC With EC
  • 1d 2,052 (76.5) 144 (77.8)
  • 2d 393 (91.2) 26 (91.9)
  • 3d 123 (95.8) 8 (96.2)
  • 4d 61 (98.1) 1 (96.8)
  • 5d 35 (99.4) 2 (97.8)
  • 6d 14 (99.9) 4 (100)
  • 7d 3 (100) -------------
  • 1Positivity of blood cultures for pathogens by
    incubation day (BACTEC 9240), ECendocarditis
  • 2Cockerill, III et al., Clin Inf Dis
    381724-1730, 2004

40
Blood Culture Systems
  • Manual
  • Septi-Chek (Becton Dickinson)
  • Isolator (Wampole)
  • Semi-Automated
  • BACTEC 460 (Becton Dickinson)
  • Automated
  • BacT/ALERT (bioMérieux)
  • BACTEC 9000 System (Becton Dickinson)
  • VersaTREK (formerly ESP System) (Trek)

41
Septi-Chek (Becton Dickinson)
  • Aerobic broth bottle with attached plastic
    paddles containing agar medium (chocolate,
    MacConkey, malt)
  • Inoculated broth bottle initially inverted to
    allow blood-broth mixture to flood the agars, and
    then each time bottle is inspected for growth
  • Paddles are visually examined once or twice daily
    for colony formation, and broth for evidence of
    microbial growth (hemolysis, turbidity, gas
    production, chocolatization of blood, visible
    colonies or layer of growth on fluid meniscus)
  • Separate anaerobic bottle without agar paddles
  • Not practical for larger laboratories due to
    manual steps required for monitoring and
    processing

42
Isolator (Wampole)
  • Isolator tube contains a blood cell lysing
    solution consisting of saponin and a fluorocarbon
    cushion that captures organisms during
    centrifugation
  • Following centrifugation supernatants are
    discarded, and pellets resuspended for
    inoculation to solid medium appropriate for type
    of culture being performed (sheep blood,
    chocolate, MAC, CNA, BCYE, IMA, Middlebrook agar)
  • Highly versatile and sensitive (except for
    anaerobic bacteria), but labor intensive for
    routine work
  • Excellent system for isolation from blood of
    Mycobacterium avium or M. tuberculosis complex,
    dimorphic fungi, Bartonella, Legionella, and
    other fastidious pathogens

43
BACTEC 460 (Becton Dickinson)
  • Blood culture broth medium (aerobic and
    anaerobic) contains 14C labeled carbohydrate
    substrate
  • With microbial growth carbohydrate substrate
    metabolized and 14C labeled CO2 gas released into
    head space of bottles
  • Needles perforate rubber septum of each bottle
    and headspace gas withdrawn for radiometric
    measurement of 14C labeled CO2
  • Bottles reaching threshold 14C levels flagged as
    positive for Grams stain and subculture of broth
    to solid medium
  • A semi-automated system that requires placement
    of racks with bottles on a shuttle of the BACTEC
    460 radiometer for testing
  • Replaced in routine work by automated blood
    culture systems
  • Remains an excellent system for recovery of
    mycobacteria from a wide variety of specimens,
    including sputum, where broth contains 14C
    labeled palmitic acid as substrate for cell wall
    mycolic acid synthesis, with release of 14C
    labeled CO2 into headspace of bottles containing
    Middlebrook broth

44
BacT/ALERT (bioMérieux)
  • The first continuous-monitoring blood culture
    system (CMBCS), introduced in early 1990s
  • Broth bottles monitored continuously (every 10-15
    min) for growth in self-contained modular units
    and bottles require no manipulation until flagged
    as positive for growth
  • Growth monitored by a colorimetric CO2 sensor at
    the base of each bottle
  • Computer algorithms interpret CO2 production as
    microbial growth when arbitrary thresholds
    exceeded, minimal linear increases of CO2 occur,
    or there is change in the rate of CO2 production

45
BACTEC 9000 System (Becton Dickinson)
  • Three instruments in the BACTEC 9000 CMBCS
    series 9050 system (monitors 50 bottles), 9120
    system (120 bottles), and 9240 system (240
    bottles)
  • Growth monitored by a fluorescent CO2 sensor at
    the base of each broth bottle
  • Computer algorithms interpret CO2 production as
    microbial growth by linear increases in
    fluorescence, and an increase in the rate of
    flouorescence

46
VersaTREK (ESP System) (Trek)
  • Third CMBCS introduced commercially
  • Differs from BacT/ALERT and BACTEC 9000 series in
    that direct measurement of CO2 production not
    utilized to monitor microbial growth
  • Bottles fitted with pressure transducers to
    monitor gas pressure changes within bottle
    headspaces
  • Computer algorithms interpret the consumption
    and/or production of gas as microbial growth in
    which pressure changes are plotted against time
    to yield growth curves
  • Positive cultures are signaled in accordance with
    these proprietary algorithms

47
Characteristics of CMBCSs
  • Microbial growth detected 1-2 days earlier than
    with manual systems (total incubation time of 5
    days)
  • Provides 24/7 service with prompt reporting of
    Grams stain results for positive blood cultures
  • Decreases laboratory workload

48
Quality management monitors
  • Contamination rate (should not exceed 3 of blood
    culture sets accessioned)
  • Identification and susceptibility testing of
    coagulase-negative stapylococci (CNS) (should not
    exceed 12-30 of blood cultures sets positive for
    CNS)
  • Blood volume (determined by broth bottles and
    blood culture systems utilized by the laboratory)

49
Probability of Same Contaminant in Two Blood
Culture Sets
  • 0.03 X 0.03 0.0009 (lt1 per 1,000 sets)
  • 36 episodes/40,000 culture sets
  • 0.05 X 0.05 0.0025 (2-3 per 1,000 sets)
  • 100 episodes/40,000 culture sets
  • 0.10 X 0.10 0.01 (1 per 100 sets)
  • 400 episodes/40,000 culture sets
  • 0.15 X 0.15 0.02 (2 per 100 sets)
  • 800 episodes/40,000 culture sets

50
CNS Algorithm
  • Single blood culture for CNS, no other blood
    cultures collected /- 48 hr Evaluation of
    patient for sepsis
  • Single blood culture for CNS, additional blood
    cultures collected /- 48 hr negative for CNS No
    ID or susceptibility unless physician request
  • Single blood culture for CNS, additional blood
    cultures collected /- 48 hr positive for CNS
    Evaluation of patient for sepsis
  • Richter et al. JCM 402437-2444, 2002.

51
CNS Algorithm
  • If 2 or more blood cultures submitted and only
    one for CNS, reported as likely contaminant (no
    species ID, no susceptibility)
  • If 1 of 1 blood culture submitted and is positive
    for CNS, reported as of indeterminate significant
    and physician advised to contact laboratory if ID
    and susceptibility needed
  • If 2 or more blood cultures submitted for CNS,
    ID and susceptibility determined if both
    isolates same species, ID and susceptibility
    reported if different species, reported only as
    CNS without species and susceptibility
  • Weinstein JCM 412275-2278, 2003.

52
References
  • Weinstein et al. The clinical significance of
    positive blood cultures in the 1990s A
    prospective comprehensive evaluation of the
    microbiology, epidemiology, and outcome of
    bacteremia and fungemia in adults. Clin Inf Dis
    24584-602, 1997.
  • Munson et al. Detection and treatment of
    bloodstream infection Laboratory reporting and
    antimicrobial management. J Clin Micro
    41495-497, 2003.
  • Jaimes et al. Predicting bacteremia at the
    bedside. Clin Inf Dis 38357-362, 2004.
  • Mohr et al. Manual and automated systems for
    detection and identification of microoranisms.
    Manual of Clinical Microbiology, Volume
    1185-191, 2003.
  • Reimer et al. Update on detection of bacteremia
    and fungemia. Clin Micro Rev 10444-465.
  • Weinstein. Current blood culture methods and
    systems Clinical concepts, technology, and
    interpretation of results. Clin Inf Dis
    2340-46, 1996.
  • Dunne et al. Blood Cultures III. Cumitech 1B,
    1997.

53
References
  • Kellogg et al. Frequency of low-level bacteremia
    in children from birth to fifteen years of age.
    J Clin Micro 382181-2185.
  • Cockerill III et al. Optimal testing parameters
    for blood cultures. Clin Inf Dis 381724-1730.
  • Weinstein et al. Remarks concerning testing
    parameters for blood cultures. Clin Inf Dis
    40202, 2005.
  • Cockerill III. Reply to Weinstein and Reller.
    Clin Inf Dis 40202-203, 2005.
  • Richter et al. Minimizing the workup of blood
    culture contaminants Implementation and
    evaluation of a laboratory-based algorithm. J
    Clin Micro 402437-2444, 2002.
  • Weinstein. Blood culture contamination
    Persisting problems and partial progress. J Clin
    Micro 412275-2278, 2003.
  • Mirrett et al. Relevance of the number of
    positive bottles in determining clinical
    significance of coagulase-negative staphylococci
    in blood cultures. J Clin Micro 393279-3281.
  • Bates et al. Contaminant blood cultures and
    resource utilization. J Am Med Assoc
    265365-369, 1991.
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