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Calculation Method for a Full-Period Consecutive Sampling

Statistical Analysis and Relevance | EXAMPLE—OUTLINE OF THE NIOSH 7400 QA PROCEDURE | Field Monitoring Procedures—Air Sample | TOXICITY ASSESSMENT | DATA EVALUATION AND DATA GAPS | Biological Risk Assessment | Figure 6.1 Biological contact agar strips. (Biotest Diagnostic Corp.) | FUNGI, MOLDS, AND RISK | BIOLOGICAL AGENTS AND FUNGI TYPES | Controlling Fungi |


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The use of multiple consecutive samples will result in slightly lower SAEs than the use of one continuous sample because the inherent errors tend to partially cancel each other. The mathematical calculations, however, are somewhat more complicated. If preferred, the industrial hygienist may first determine if compliance or noncompliance can be established using the calculation method noted for a full-period, continuous, single-sample measure­ment. If results fall into the "possible overexposure" region using this method, a more exact calculation should be performed as follows.


Compile X(l), X(2)..., Х(и), and the n consecutive concentrations on one workshift.

Compile their time durations, T(l), T(2),..., T(n).

Compile the SAE.

Compute the TWA exposure.

Divide the TWA exposure by the PEL to find Y, the standardized average (TWA/PEL).

Compute the UCL (95%) as follows: UCL (95%) = Y + SAE (Equation E).

Compute the LCL (95%) as follows: LCL (95%) = Y - SAE (Equation F).

Classify the exposure according to the following classification system:

• If the UCL < 1.0, a violation does not exist.

• If the LCL < 1.0, and the UCL > 1, classify as possible overexposure.

• If the LCL > 1.0, a violation exists.

When the LCL < 1.0 and the UCL > 1.0, the results are in the "possible overexposure" region, and the industrial hygienist must analyze the data using the more exact calculation for full-period consecutive sampling, as follows:

Y - SAE(T12X12 + T2%2... + Т 2Хп2)1'2 РЕЦТ + T2 + Т„)

4.6.4 Sample Calculation for Full-Period Consecutive Sampling

Two consecutive samples were taken for carbaryl instead of one continuous sample, and the following results were obtained:

Sample А В

Sampling rate (L/min) 2.0 2.0

Time (min) 240.0 210.0

Volume (L) 480.0 420.0
Weight (mg) 3.005 2.457
Concentration (mg/m3) 6.26 5.85

The SAE for carbaryl is 0.23.

Step 1. Calculate the UCL and the LCL from the sampling and analytical results: TWA = (6.26 mg/m3 X 240 min + (5.85 mg/m3) X 210 min 450 min = 6.07 mg/m3 Y = 6.07 mg/m3/PEL = 6.07/5.0 = 1.21 Assuming a continuous sample: LCL = 1.21 - 0.23 = 0.98

UCL = 1.21 + 0.23 = 1.44

Step 2. Since the LCL < 1.0 and the UCL > 1.0, the results are in the possible over-exposure region, and the industrial hygienist must analyze the data using a more exact calculation for full-period consecutive sampling. If the LCL > 1.0, a violation is established.


4.7 GRAB SAMPLING

If a series of grab samples (e.g., detector tubes) is used to determine compliance with either an 8-h TWA limit or a ceiling limit, consult with an industrial hygienist (ARA) regarding sampling strategy and the necessary statistical treatment of the results obtained.

4.8 SAES—EXPOSURE TO CHEMICAL MIXTURES

Often an employee is simultaneously exposed to a variety of chemical substances in the workplace. Synergistic toxic effects on a target organ are common for such exposures in many construction and manufacturing processes. This type of exposure can also occur when impurities are present in single chemical operations. New PELs for mixtures, such as the recent welding fume standard (5 mg/m3), addresses the complex problem of synergis­tic exposures and their health effects. In addition 29 CFR 1910.1000 contains a computa­tional approach to assess exposure to a mixture. This calculation should be used when components in the mixture pose a synergistic threat to worker health.

Whether using a single standard or the mixture calculation, the SAE of the individual constituents must be considered before arriving at a final compliance decision. These SAEs can be pooled and weighted to give a control limit for the synergistic mixture. To illustrate this control limit, the following example using the mixture calculation is shown. The mix­ture calculation is expressed as:

Em = (Q/L, + C2/L2) +... Q/LJ where

• Em = equivalent exposure for a mixture (Em should be < 1 for compliance)

• С = concentration of a particular substance

• L = PEL

For example, to calculate exposure to three different, but synergistic substances:

Material 8-h exposure 8-h TWA PEL (ppm) SAE

Substance 1 500 1000 0.089

Substance 2 80 200 0.11

Substance 3 70 200 0.18

Using Equation I: Em = 500/1000 + 80/200 + 70/200 = 1.25

Since Em > 1, an overexposure appears to have occurred; however, the SAE for each substance also needs to be considered:

• Exposure ratio (for each substance): Yn = Cn/LK

• Ratio to total exposure: Rj = Yj/Eml... Rn = Yn/Em

• The SAEs (95% confidence) of the substance comprising the mixture can be
pooled by:

(RSt2) = [(R*) (SAE^) + (R22) (SAE22) +... (Rn2) (SAEn2)]


The mixture control limit (CL) is equivalent to 1 + RSt.

—If Em < CLj, then an overexposure has not been established at the 95% confi­dence level; further sampling may be necessary. —If Em > 1 and Em > CLj, then an overexposure has occurred (95% confidence).

Using the mixture data above:

= 80/200 Y3 = 70/200
= 0.4 Y3 = 0.35
= 0.32 R, = 0.28

Y, = 500/1000 Y, = 0.5


• (RSt)2 = (0.42)(0.0892) + (0.322)(0.112) + (0.282)(0.182)

• RSt = [(RSt)2)](l/2) = 0.071

• CL = 1 + RSt = 1.071

• Em = 1.25

Therefore Em > CL and an overexposure has occurred within 95% confidence limits. This calculation is also used when considering a standard such as the one for total welding fumes.


CHAPTER 5


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