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Potential uses of EBV and CMV viral load assays

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Potential uses of EBV and CMV viral load assays ... Dr Jutta K Preiksaitis. Provincial Public Health Laboratory (Alberta) University of Alberta ... – PowerPoint PPT presentation

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Title: Potential uses of EBV and CMV viral load assays


1
Potential uses of EBV and CMV viral load assays
  • In solid organ and hematopoietic stem cell
    transplantation
  • As triggers for pre-emptive therapy for disease
    prevention
  • For disease diagnosis
  • For treatment monitoring
  • As surrogate markers of anti-viral resistance
  • For safety monitoring in clinical trials (new
    immunosuppressive agents)
  • Other
  • Disease diagnosis and treatment monitoring other
    EBV-related disease- nasopharyngeal carcinoma ,NK
    and Hodgkins lymphoma
  • Population based screening- congenital CMV
    disease

2
CMV and EBV Viral Load AssaysCurrent Problems
  • Many In-house not standardized or cross
    referenced
  • Optimal sampling site uncertain - serum,
    Leukocytes/lymphocytes, whole blood
  • Optimal sampling frequency uncertain
  • Natural history studies are scarce so that
    trigger points for intervention have not been
    clearly defined

3
Development of an International Standard for EBV
and CMV Viral Load Assessment
  • Dr Jutta K Preiksaitis
  • Provincial Public Health Laboratory (Alberta)
  • University of Alberta
  • Edmonton and Calgary, Alberta Canada
  • On behalf of the American Society of
    Transplantation Infectious Diseases Community of
    Practice and the Canadian Society of
    Transplantation

4
Objective of Study
  • To examine the inter-laboratory variability in
    qualitative and quantitative CMV and EBV viral
    load assessments
  • Funded by the American Society of Transplantation
    and the Canadian Society of Transplantation (
    arms-length educational grant Roche Canada)
  • Coordinated through the American Society of
    Transplantation Infectious Diseases Community of
    Practice

5
  • CMV Viral Load Assays

6
Establishing the expected result
  • Viral stock (purified nucleocapsids of Merlin, a
    clinical isolate in human in CMV seronegative
    human plasma)
  • Quantified by nucleocapsid count using electron
    microscopy log 10 copies/ml 4.52
  • Calculation of a mean of replicate viral load
    results from seven reference laboratories
    (included use of all available commercial assays)
    log 10 copies/ml 5.0

7
Panel Design
  • 12 samples
  • 2 negatives (CMV seronegative plasma)
  • 7 samples -dilutions of purified viral stock
    replicates of two dilutions were included
  • 3 clinical samples (130 dilution in CMV
    seronegative plasma)
  • UL54 mutation (not ganciclovir resistant)
  • UL97mutation (ganciclovir resistant) and gB
    mutation
  • No mutation

8
CMV PCR Methods Utilized n35 panels (33
labs)19 US, 12 Canada , 2 EU
9
Results Summary 35 panels / 33 laboratories
CMV DNA Copies/ml (log10)
CMV DNA Copies/ml (log10)
CMV Sample Number
10
Summary of CMV Qualitative Results (constructed
samples) 35 panels / 33 labs
Sample No EM based expected result copies/ml (log10) Reference lab expected result copies/ml (log10) Number of panels Number of panels Number of panels
Sample No EM based expected result copies/ml (log10) Reference lab expected result copies/ml (log10) Negative () Positive-NQ () Positive-Q ()
02 0.0 0.0 34 (97) 0 1 (3)
09 0.0 0.0 33 (94) 0 1 (3)
07 1.5 2.0 26 (74) 6 (17) 3 (9)
08 2.5 3.0 4 (11) 4 (11) 27 (77)
04 3.5 4.0 0 1 (3) 34 (97)
11 3.5 4.0 0 2 (6) 33 (94)
03 4.5 5.0 0 0 35 (100)
12 4.5 5.0 0 0 35 (100)
06 5.5 6.0 0 0 35 (100)
One test was invalid Pos-NQ positive but not
quantifiable Pos-Q positive with quantifiable
results
11
Summary of CMV Quantitative results (constructed
samples) 35 panels / 33 laboratories
Sample No EM based expected result copies/ml (log10) Reference lab expected result copies/ml (log10) Number positive GM ?SD copies/ml (log10) Median (range) copies/ml (log10)
07 1.5 2.0 9 2.2 ? 0.44 0 (0-2.78)
08 2.5 3.0 31 3.1 ? 0.58 3.01 (0-4.32)
04 3.5 4.0 35 3.89 ? 0.52 4.02 (2.33-5.08)
11 3.5 4.0 35 3.84 ? 0.52 3.95 (2.62-5.01)
03 4.5 5.0 35 4.83 ? 0.44 4.89 (3.42-5.89)
12 4.5 5.0 35 4.80 ? 0.49 4.90 (3.68-5.91)
06 5.5 6.0 35 5.59 ? 0.52 5.51 (4.65-6.73)
Geometric mean negative results were excluded
12
CMV quantitative results relative to expected
result reference labs as gold standard
Number of panel results falling within specified parameter relative to expected result reference labs (copies/ml, log10) Number of panel results falling within specified parameter relative to expected result reference labs (copies/ml, log10) Number of panel results falling within specified parameter relative to expected result reference labs (copies/ml, log10) Number of panel results falling within specified parameter relative to expected result reference labs (copies/ml, log10)
Sample No positive log0.2 () log0.5 () log1 () gt log1 ()
07 9 2 (22) 7 (78) 9 (100) 0
08 31 8 (26) 21 (68) 27 (87) 4 (13)
04 35 17 (49) 26 (74) 33 (94) 2 (6)
11 35 16 (46) 25 (71) 32 (91) 3 (9)
03 35 19 (54) 25 (71) 34 (97) 1 (3)
12 35 16 (46) 25 (71) 32 (91) 2 (6)
06 35 7 (20) 15 (43) 32 (91) 3 (9)
negative results were excluded
13
CMV Qualitative and Quantitative results
(clinical samples) 35 panels / 33 laboratories
Clinical Sample Number Clinical Sample Number Clinical Sample Number
10 05 01
Qualitative Result Negative () 13 (37) 0 0
Qualitative Result Pos-NQ () 9 (26) 1 (3) 0
Qualitative Result Pos-Q () 13 (37) 34 (97) 35 (100)
Quantitative Result copies/ml (log10) GM?SD 2.78 ? 0.72 3.89 ? 0.53 3.97 ? 0.47
Quantitative Result copies/ml (log10) Median (range) 2.24 (0-4.18) 3.87 (2.73-4.89) 3.99 (3.08-5.05)

GMGeometric mean negative results were
excluded
14
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15
Comparison of Intra and Inter laboratory
variation in CMV vial load assessments in
duplicate specimens
mean coefficient of variation (CV), mean coefficient of variation (CV), mean coefficient of variation (CV),
Duplicate samples (sample 04 and 11) 35 panels Duplicate samples (sample 03 and 12) 35 panels p value
Intra-Lab 21.48 17.62 0.720
Inter-Lab 149.23 139.15 0.316
p value lt 0.0001 lt 0.0001
Fisher Exact Test (two tailed)
16
CMV Conclusions
  • Significant variation exists in reported results.
    The greatest variation was observed in clinical
    samples and constructed samples with low viral
    load. As viral load increased, there was less
    variation independent of the assay platforms used
    (commercial versus in-house)
  • False negative results were not observed in
    samples with viral load greater than 3.0 log
    copies/ml (expected result) even when lower limit
    of detection reported was higher than this value
  • Variation is lower limits of detection may have
    significant impact on duration of treatment based
    on recommendation of treatment until viral load
    is non-detectable
  • If 0.5 log10 is considered acceptable assay
    variation, only 62.5 of the results observed
    fell within this range

17
CMV Conclusions
  • As a group, commercial assays demonstrated
    overall less variability compared to all in
    house developed assays, but some of the former
    have limitations related to lower sensitivity and
    limited dynamic range
  • Inter-laboratory variability was significantly
    greater than intra-laboratory variability,
    highlighting the need for an international
    reference standard for assay calibration

18
  • EBV Viral Load Assays

19
Establishing the expected result
  • EBV viral stock (Namalwa cell line in EBV
    seronegative plasma)
  • Quantified by Namalwa cell count using assumption
    of 2 EBV genome copies per cell
  • Calculation of a geometric mean of replicate
    viral load results from seven reference
    laboratories ( included use of all available
    commercial assays)

20
Panel Design
  • 12 samples
  • Constructed samples-(total cell count in each
    sample fixed to mimic total white cell count in
    normal peripheral blood)
  • 2 negatives ( EBV-negative Molt-3 cells in EBV
    seronegative plasma)
  • 7 samples -dilutions of EBV-positive Namalwa
    cells and EBV-negative Molt-3 cells two
    dilutions were replicated
  • 3 clinical plasma samples (diluted in EBV
    seronegative plasma)
  • Two patients had EBV-positive B cell
    post-transplant lymphoproliferative disorder

21
EBV PCR Methods Utilized n30 panels (28
labs)16 US, 11 Canada, 2 EU
22
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23
Summary of EBV Qualitative Results (constructed
samples) 30 panels reported from 28 laboratories
Sample No. ?Expected result based on Namalwa cell count copies/ml (log10) Number of panels Number of panels Number of panels
Sample No. ?Expected result based on Namalwa cell count copies/ml (log10) Negative () Positive-NQ () Positive-Q ()
01 0.0 30 (100) 0 0
08 0.0 28 (93) 0 2 (7)
09 1.3 27 (90) 1 (3) 2 (7)
03 2.3 16 (53) 3 (10) 11 (37)
05 3.3 3 (10) 2 (7) 25 (83)
10 3.3 3 (10) 1 (3) 26 (87)
02 4.3 0 1 (3) 29 (97)
11 4.3 0 2 (7) 28 (93)
06 5.3 0 1 (3) 29 (97)
? Quantitation based on cell count Pos-NQ
positive, not quantifiable Pos-Q positive,
quantifiable
24
Summary of EBV Quantitative results (Constructed
Samples) 30 panels reported from 28 labs
Sample No. Expected result based on Namalwa cell count copies/ml (log10) Number of positive results GM? SD copies/ml (log10) Median (range) copies/ml (log10)
09 1.3 3 1.89?0.93 0.00 (0.00- 2.74)
03 2.3 14 2.48?0.59 0.00 (0.00- 3.78)
05 3.3 27 2.97?0.52 2.92 (0.00-4.14)
10 3.3 27 3.02?0.61 2.92 (0.00-4.12)
02 4.3 30 3.92?0.59 4.03 (2.76-5.04)
11 4.3 30 3.88?0.66 3.97 (2.18-5.00)
06 5.3 30 4.81?0.81 4.96 (2.15-6.09)
Geometric mean negative results were excluded
25
EBV quantitative results (constructed samples)
relative to expected result Namalwa cell count
as gold standard
Number of panel results falling within specified parameter relative to expected result Namalwa cell count (copies/ml, log10) Number of panel results falling within specified parameter relative to expected result Namalwa cell count (copies/ml, log10) Number of panel results falling within specified parameter relative to expected result Namalwa cell count (copies/ml, log10) Number of panel results falling within specified parameter relative to expected result Namalwa cell count (copies/ml, log10)
Sample No Number positive results log0.2 () log0.5 () log1 () gt log1 ()
09 3 0 1 (33) 1 (33) 2 (67)
03 14 3 (21) 10 (71) 12 (86) 2 (14)
05 27 5 (19) 16 (59) 26 (96) 1 (4)
10 27 6 (22) 14 (52) 25 (93) 2 (7)
02 30 10 (33) 17 (63) 25 (83) 5 (17)
11 30 8 (27) 15 (50) 25 (83) 5 (17)
06 30 4 (13) 17 (57) 25 (83) 5 (17)
negative results were excluded
26
EBV Qualitative and Quantitative results
(clinical samples) 30 panels reported from 28
labs
Clinical Sample Number Clinical Sample Number Clinical Sample Number
07 04 12
Qualitative Result Negative () 0 0 0
Qualitative Result Pos-NQ () 0 0 0
Qualitative Result Pos-Q () 30 (100) 30 (100) 30 (100)
Quantitative Result copies/ml, log10 GM?SD 4.08 ? 0.60 3.95 ? 0.56 4.21 ? 0.61
Quantitative Result copies/ml, log10 Median (range) 4.09 (3.09- 5.12) 3.96 (3.10 5.31) 4.36 (3.08 5.12)
GM Geometric mean
27
Result linearity over dynamic range (each line
represents results from one lab)
28
Comparison of Intra and Inter laboratory
variation in EBV vial load assessments in
duplicate specimens
Mean coefficient of variation (CV), Mean coefficient of variation (CV), Mean coefficient of variation (CV),
Duplicate (sample 05 and 10) 25 panels Duplicate (sample 02 and 11) 30 panels p value
Intra-Lab 39.01 30.48 0.234
Inter-Lab 135.56 135.26 1.0
p value lt 0.0001 lt 0.0001
Fisher Exact Test (two tailed)
29
Conclusions
  • Significant variation in reported results exists
    in all samples independent of viral load and of
    assay platforms used (commercial versus in-house)
  • If 0.5 log10 is considered acceptable
    variation in a Q NAT assay, our results indicate
    that only 56 of all results fell within that
    parameter
  • Greater QNAT variations were observed in cellular
    constructed samples when compared to acellular
    plasma samples indicating that DNA extraction in
    cellular samples may need further improvement
  • Inter-laboratory variability was significantly
    greater than intra-laboratory variability,
    highlighting the need for an international
    reference standard for assay calibration

30
Next Steps
  • Highest Priority
  • Establishment of an international reference
    standard for EBV and CMV qualitative and
    quantitative assay calibration

31
Acknowledgments
  • Technical Committee
  • Dr Xiao-Li Pang
  • Dr Julie Fox
  • Dr Geraldine Miller
  • Dr Angie Caliendo
  • Technical and other support
  • Jayne Fenton
  • Sandra Shokopoles
  • Kim Martin
  • Ana Shynader
  • AST ID Community of Practice
  • Dr John Saldanha
  • Dr Alan Heath

32
Participating Laboratories
  • USA
  • UCLA Healthcare Clinical Labs, Los Angeles
  • Stanford Hospital and Clinics, Stanford
  • Yale-New Haven Hospital, New Haven
  • Emory Hospital, Atlanta
  • University of Iowa, Iowa City
  • University of Chicago Hospitals, Chicago
  • Johns Hopkins Hospital, Baltimore
  • University of Michigan Medical Center, Ann Arbor
  • Warde Medical Laboratory, Ann Arbor
  • Mayo Clinic, Rochester
  • St. Louis Childrens Hospital, St. Louis
  • Viracor Laboratories, Lees Summit
  • University of North Carolina Hospital, Chapel
    Hill
  • Mt. Sinai Hospital, New York
  • Cleveland Clinic, Cleveland
  • Oregon Health Science University, Portland
  • Childrens Hospital of Pittsburgh, Pittsburgh
  • Vanderbilt University Medical Center, Nashville
  • Canada
  • Childrens Hospital of British Columbia,
    Vancouver
  • St. Pauls Hospital, Vancouver
  • Provincial Laboratory for Public Health Alberta,
    Edmonton Calgary
  • National Microbiology Laboratory, Winnipeg
  • St. Josephs Health Care, Hamilton
  • Hospital for Sick Children, Toronto
  • Mt. Sinai Hospital, Toronto
  • Childrens Hospital of Eastern Ontario, Ottawa
  • London Laboratory Services, London
  • St. Justine Hospital, Montreal
  • Centre hospitalier de l'Université Laval, Quebec
    City
  • QE II Health Sciences Centre, Halifax
  • Newfoundland Public Health Laboratory, St. Johns
  • Europe
  • Erasmus MC, University Medical Center Rotterdam,
    The Netherlands
  • Institute for Medical Microbiology, Basel,
    Switzerland
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