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APPLICATION OF MICROTESTER FOR DETECTION OF LOW MICROBIAL CONTAMINATION Oliver Reichart Katalin Szakmár
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Page 1: Application of MicroTester for detection of low microbial contamination

APPLICATION OF MICROTESTER FOR DETECTION OF LOW

MICROBIAL CONTAMINATION

Oliver ReichartKatalin Szakmár

Page 2: Application of MicroTester for detection of low microbial contamination

Classical microbiological methods

Long incubation time (1-4 days)

The applicability, reliability and test prices of the methods are concentration-dependent:

High concentration: dilution and colony counting in the

range of 30-300 cfu/ml.

Low concentration: Membrane filtration

Page 3: Application of MicroTester for detection of low microbial contamination

The Microtester method

The energy source of the growth is the biological oxidation which results in a reduction in the environment.

Due to the oxygen depletion and the production of reducing compounds the redox-potential of the nutrient medium changes.

The redox-potential of the medium is a well measurable parameter which could be used for the determination of the microbial multiplication.

Page 4: Application of MicroTester for detection of low microbial contamination

MicroTester System, 32 Channels

Water baths Test cellsMeasuring

modulesComputer,

Monitor

Page 5: Application of MicroTester for detection of low microbial contamination

Direct test cells

Page 6: Application of MicroTester for detection of low microbial contamination

Indirect test-cell

Page 7: Application of MicroTester for detection of low microbial contamination

Redox-curves of several bacteria

Redox curves in TSB (T=30°C)

-400

-200

0

200

400

0 2 4 6 8 10 12 14 16 18

t (h)

Eh

(m

V)

steril Ps.aer. E.coli St. aur. Ent. faec. B.subt.

Page 8: Application of MicroTester for detection of low microbial contamination

Characteristics of the redox-curves

E. coli 37 °C in TSB

-400-300-200-100

0100200300400500

0 1 2 3 4 5 6 7 8 9

t (h)

Eh

(m

V)

3

4

5

6

7

8

9

log

N

Eh logN

log No TTD

log Nc

|dE/dt|>DC

Page 9: Application of MicroTester for detection of low microbial contamination

Detection criterion (DC)The detection criterion is the critical rate of the change of redox-potential (dE/dt, the slope of the redox curve) which is significantly differing from the random fluctuation and could be ascribed to the multiplication of the microbes. (e.g. DC = |dE/dt| = 0.5 mV/min).

Detection time (TTD)The detection time (TTD) is that moment when the absolute value of the rate of redox potential change in the measuring-cell exceeds the detection criterion. |dE/dt| DC mV/min).

As the critical rate of the redox potential decrease needs a well-defined critical cell number (Nc = 107 cfu/ml) the detection time depends on the initial microbial count, N0.

Characteristics of the redox-curves

Page 10: Application of MicroTester for detection of low microbial contamination

Positive detection

In the inoculated medium the microbes after the lag phase start to multiply. Due to their metabolism the redox-potential decreases in the test cell.

After a time (depending on the inoculum size) the rate of decrease exceeds the detection criterion. The system gives a TTD value which refers to the presence of multiplying microorganisms (in about 106-107 cfu/ml concentration).

Keeping on the redox-measurement appears a typical redox-curve characterizing on the microbe or microbial group growing in the test cell.

As a result of the multiplication we get a suspension of 107-108 cfu/ml with visual turbidity.

Page 11: Application of MicroTester for detection of low microbial contamination

False positive detection in selective medium

In case of massive inoculation (i.e. from the surface of solid medium with a loop) the initial microbe concentration in the test cell could exceed the value of 107-108 cfu/ml and causes visual turbidity.

The exo-enzymes and metabolites of the inoculum start immediately to reduce the redox-potential of the medium which could result in TTD detection in the initial concave section of the redox-curve.

As the multiplication is inhibited by the selective medium the characterising convex section of the redox-curve does not evolve.

Page 12: Application of MicroTester for detection of low microbial contamination

Redox curves in cetrimide broth

Growth in cetrimide broth

0

100

200

300

400

500

0 5 10 15 20

time (h)

Eh

(m

V)

Ps4 Ps5 Ps6 Ps. fluorescens E. coli Enterococcus

Page 13: Application of MicroTester for detection of low microbial contamination

Effect of the inoculum size on the redox-curves

TTD for the redox-potential measurement is: |E/ t|>1mV/min

E. coli, TSB, 37 °C

-400

-200

0

200

400

0 2 4 6 8 10 12 14

t (h)

Eh

(m

V)

Sterile lgN=0,09 lgN=2,38 lgN=3,39 lgN=4,25 lgN=4,80

Page 14: Application of MicroTester for detection of low microbial contamination

Effect of the initial cell concentration on TTD

E.coli, TSB, 37 °C y = -1,1996x + 8,3112

R2 = 0,9795

0

2

4

6

8

10

0 1 2 3 4 5

logN (cfu/inoculum)

TT

D (

h)

Page 15: Application of MicroTester for detection of low microbial contamination

Calibration curves

Strict linear relationship exists between the logarithm of the viable count of the test cell inoculum, log N(c) and the detection time (TTD) which is represented by the calibration curve.

The equation of the calibration curve makes possible to calculate the viable cell count on the base of TTD in a very wide range:

log N(c) = A · TTD + B

The calibration curves refer on the test cell and the microbial contamination of the sample is calculated by the software automatically.

Page 16: Application of MicroTester for detection of low microbial contamination

MPN calibration curves

MPN calibration curve is applied when the previously constructed calibration curve cannot be taken. In this case, the redox potential measurement could be combined with the MPN method and the software makes possible the on-line determination the most probable microbial count and the calibration curve.

From the sample the usual dilution series is prepared up to a dilution which is free of microbe. In case of low cell numbers apply membrane filtering.

Place the membranes into the measuring cells and record the redox curves.

Page 17: Application of MicroTester for detection of low microbial contamination

Redox-curves for the E. coli calibration

Page 18: Application of MicroTester for detection of low microbial contamination

Determination of the calibration curve

Based on the last dilution level still showing multiplication (TTD), the most probable cell-number of the undiluted (most concentrated) sample, MPN(0) is determined automatically by the program.

With the knowledge of MPN(0) and TTD values belonging to the several dilutions, the software calculates the equation of the log MPN calibration.

Having determined the microbial contamination of the sample with a classical reference method and inputting the result, the system automatically recalculates the MPN calibration to logN calibration.

Page 19: Application of MicroTester for detection of low microbial contamination

MPN calibration

Page 20: Application of MicroTester for detection of low microbial contamination

MPN and logN calibration

Page 21: Application of MicroTester for detection of low microbial contamination

Calibration curve

E. coli, membrane filtering, V = 100 ml

0

2

4

6

8

10

0 2 4 6 8 10

TTD (h)

log

N(c

) logN(c) = - 0.933·TTD + 9.099

Page 22: Application of MicroTester for detection of low microbial contamination

Redox-curves. How long to measure?

If we have got TTD value it is proposed to continue the measurement until the redox curve is taking shape.

Having no TTD it is proposed to measure until the estimated microbial count in the test cell (calculated by the calibration curve) drops below 1/100, logN(c) < -2.

Page 23: Application of MicroTester for detection of low microbial contamination

Time to „detection no microbe”, TTDN

In the test cell

logN(c) ≤ -2

logN(c) = A·TTD + B

TTD = [logN(c) – B] / A

A = -0.933 h-1 B = 9.099

Time to detection no microbe: TTDN ≥ 11.2 h

Page 24: Application of MicroTester for detection of low microbial contamination

Time to „detection no microbe”, TTDN

 Microbe/medium Medium Calibration TTDN

(ml) A (h-1) B (h)

E. coli 15 -0,627 8,307 16,4

BBL 44 °C 50 -0,854 10,260 14,4

Cb. freundii 15 -0,420 7,449 22,5

BBL 37 °C 50 -0,667 10,332 18,5

Ps. aeruginosa 15 -0,595 9,456 19,2

Cetrimide 37 °C 50 -0,513 11,111 25,6

Entc. faecalis 15 -0,406 7,645 23,7

Azide 37 °C 50 -0,480 9,482 23,9

Page 25: Application of MicroTester for detection of low microbial contamination

Application for low microbial contamination

Membrane filteringMicrobe concentration of the sample: N(0) cfu/ml

Volume of the filtered sample: V(0) mlDetection limit in the test cell: N(c)min = 1 cfu/test cellDetection limit of the sample: N(0)min = N(c)min/V(0)

N(0)min = 1/V(0) cfu/ml

Do not forget:In the low microbial concentration range the probability of the detection is highly affected by the test volume.

Page 26: Application of MicroTester for detection of low microbial contamination

Linearity of membrane filtering

E. coli, BBL 37 °C y = -1,12x + 9,1972

R2 = 0,9871

0

2

4

6

8

10

-1 0 1 2 3 4 5 6

logN(c) (cfu/cell)

TT

D (

h)

membrane 1 ml

Page 27: Application of MicroTester for detection of low microbial contamination

Detection of microbial contamination

Sampling and testing the product

To find the defective unit and detect the contamination

Distribution of micro-organisms in the product

Contagious distribution (б2>µ)

Sporadic occurrence of defective units

Main problem is to find the defective units

Random distribution (б2=µ)

Main problem is to detect the low microbial count

Basic assumption: Even one viable cell results in positive test.

Page 28: Application of MicroTester for detection of low microbial contamination

Effect of the test volume on the detection

Legends

Ns : average microbe-concentration of the sample

(cfu/ml)

Vs : sample-volume (ml)

n : sample size

Vi : The total volume tested Vi = Vs · n

Ni : Inoculated total cell number in the all tests (cfu)

Ni = Ns ·Vi

Page 29: Application of MicroTester for detection of low microbial contamination

Probability of positive test

Zero tolerance, positive test is not allowed

The probability of n negative test:

The probability of minimum 1 positive test:

iNeNPn eg tP

)0(

iNen eg tPNP

p o s tP

11)0(

Page 30: Application of MicroTester for detection of low microbial contamination

Comparison of the classical and redox methods

At a given microbial concentration the effectiveness of the testing depends on the filtered volume: Vi = Vs ·n

Example for mineral water testing: Vs = 250 ml/sample

Classical membrane filtration,

1 membrane for 3 samples

1 Petri dish for 1 membrane = 3 samples

Microtester method with normal loading

1 membrane for 4 samples

1 test cell for 5 membranes = 20 samples

Page 31: Application of MicroTester for detection of low microbial contamination

Probability of positive test

Membrane filtration

0,0

0,2

0,4

0,6

0,8

1,0

-6 -5 -4 -3 -2logN/ml sample

Pp

os

Vi (ml) = 75000 Vi (ml) = 40000 Vi (ml) = 18000

N = 0.01cfu/L cfu/L

N = 1cfu/L

Page 32: Application of MicroTester for detection of low microbial contamination

Probability of positive test

Membrane filtration

0,0

0,2

0,4

0,6

0,8

1,0

0,0 0,1 0,2 0,3 0,4

cfu/1000ml sample

Pp

os

n = 300 n = 160 n = 72

Vs = 250 ml

Page 33: Application of MicroTester for detection of low microbial contamination

Presence/Absence tests 1.

72 bottles tested for Coliform (09 Aug 2005)Method of Laboratory, Tergitol agar, 24 Petri dishesMembrane filtering 3 x 250 ml with 1 filter.Placing 1 filter in a Petri dishOne Petri dish represents 3 bottles All negativeDetection threshold: 1 microbe/750mlRedox potential method, BBL broth, 6 Channels, Membrane filtering 3 x 250 ml with 1 filter. Placing 4 filters in a test cell.One test cell represents 12 bottles All negativeDetection threshold: 1 microbe/3000ml

Positive control:1 ml Citrobacter freundii suspension (logN = 3.66)

Page 34: Application of MicroTester for detection of low microbial contamination

Advantages of the redox method in the evaluation of membrane filtration

The time requirement of the redox-potential technique is significantly lower than that of the classical nutrient methods.

While the classical methods use only 1 membrane in 1 Petri dish the redox-potential method makes possible to evaluate even 5 or more filters in one test cell. That means not only a 5 times lower detection limit of microbes but results in a remarkable cost reduction as well.