CATECHOL
(PYROCATECHOL)
| Method number: | PV2014 |
| Matrix: | Air |
| Target concentration: | 5 ppm (20 mg/m3) OSHA TWA PEL |
| Procedure: | Samples are collected by drawing a known volume of air through an OVS-7 tube. Samples are desorbed with methanol and analyzed by gas chromatography with a flame ionization detector (GC-FID). |
| Air volume and sampling rate studied: | 100 liters at 1.0 Lpm. |
| Status of method: | Stopgap method. This method has been only partially evaluated and is presented for information and trial use. |
| Date: August, 1992 | Chemist: Mary E. Eide |
Organic Service Branch I
OSHA Salt Lake Technical
Center
Salt Lake City, Utah
1. General Discussion
- 1.1. Background
- 1.1.1. History of procedure
The OSHA Technical Center has received many requests for a
sampling and analytical procedure for catechol. OSHA promulgated an
exposure standard for catechol of 5 ppm (20
mg/m3) TWA. OSHA method 32 recommends
collection of phenol and cresol on
1.1.2. Potential workplace exposure (Ref. 5.2. and 5.3.)
Catechol is used as a topical antiseptic, reagent, antifungal preservative on seed potato pieces, photographic developer, and developer in fur dyes. Catechol is used as an antioxidant in many industries including rubber, chemical, dye, photographic, pharmaceutical, fat, cosmetics, and oil.
1.1.3. Toxic Effects (This section is for information purposes and should not be taken as the basis for OSHA policy.)(Ref. 5.3.)
The lethal human dose of catechol is 50 to 500 grams/kilogram, or 1 teaspoon to 1 ounce for a 70 kilogram (150 pound) person, with death resulting from pulmonary failure. Catechol is a skin, eye, mucous membrane, and pulmonary irritant. It is readily absorbed from the gastrointestinal tract, and through the skin. Catechol can cause elevated blood pressure through vasoconstriction, degeneration of the renal tubes in the kidneys, and diminished liver function.
1.1.4. Physical properties (Ref. 5.2.):
| Compound: |  |
| Synonyms: | 1,2-Benzenediol; |
| Molecular weight: | 110.11 |
| Melting point: | 105°C |
| Boiling point: | 245.5°C |
| Flash point: | 127°C (261°F) |
| Odor: | faintly musty phenolic |
| Color: | colorless to white crystals |
| Molecular formula: | C6H6O2 |
| CAS: | 120-80-9 |
| IMIS: | 0571 |
| RTECS: | 73250; UX1050000 |
1.2. Limit defining parameters
- 1.2.1. The detection limit of the analytical procedure is 2.1
µg/mL catechol in the desorbing solvent. This is the smallest amount
that could be detected under normal operating conditions.
1.2.2. The overall detection limit is 0.014 ppm catechol. (All ppm amounts in this study are based on a 100 liter air volume and 3 mL desorption.)
1.3. Advantages
- 1.3.1. The sampling procedure is convenient.
1.3.2. The analytical method is reproducible and sensitive.
1.3.3. Reanalysis of samples is possible.
1.3.4. It may be possible to analyze other compounds at the same time.
1.3.5. Interferences may be avoided by proper selection of column and GC parameters.
1.4. Disadvantages
none known
2. Sampling procedure
- 2.1. Apparatus
- 2.1.1. A calibrated personal sampling pump, the flow of which
can be determined within ± 5% at the recommended flow.
2.1.2. The sampling media consists of OVS-7 tubes. The OVS-7
tubes are specially made 13 mm O.D.. glass tubes that are tapered to
6 mm O.D.. These tubes are packed with a 13 mm diameter glass fiber
filter then a 270 mg sampling section followed by a 140 mg backup
section of purified
2.2. Sampling technique
- 2.2.1. Remove the end caps of the OVS-7 immediately before
sampling.
2.2.2. Connect the OVS-7 to the sampling pump with flexible tubing.
2.2.3. Place the tubes in a vertical position to minimize section towards the channeling, with the smaller pump.
2.2.4. Air being sampled should not pass through any hose or
tubing before entering the
2.2.5. Seal the OVS-7 with plastic caps immediately after
sampling. Seal each sample lengthwise with OSHA
2.2.6. With each batch of samples, submit at least one blank tube from the same lot used for samples. This tube should be subjected to exactly the same handling as the samples (break ends, seal, & transport) except that no air is drawn through it.
2.2.7. Transport the samples (and corresponding paperwork) to the lab for analysis.
2.2.8. Bulks submitted for analysis must be shipped in a separate mailing container from other samples.
2.3. Desorption efficiency
- 2.3.1. Two hundred seventy milligram portions of XAD-7 resin
were placed into separate 4 mL vials and six portions were spiked at
each loading of 0.205 mg (0.455 ppm), 1.02 mg (2.26 ppm), 2.05 mg
(4.55 ppm), and 4.01 mg (8.9 ppm) catechol, and allowed to
equilibrate overnight at room temperature. They were desorbed with 3
mL of the desorbing solution for 30 minutes with occasional shaking,
and analyzed by
Table 1
Desorption Efficiency
|
| ||||
| Portion | % Recovered | |||
| # | 0.205 mg | 1.02 mg | 2.05 mg | 4.01 mg |
|
| ||||
| 1 | 99.1 | 99.1 | 99.8 | 95.0 |
| 2 | 96.6 | 99.7 | 99.0 | 97.0 |
| 3 | 97.2 | 98.1 | 100 | 99.5 |
| 4 | 98.6 | 98.7 | 97.4 | 97.1 |
| 5 | 98.4 | 99.1 | 96.5 | 98.6 |
| 6 | 97.5 | 97.3 | 98.5 | 96.4 |
| average | 97.9 | 98.7 | 98.5 | 97.3 |
| overall average 98.1 | ||||
| standard deviation ± 1.28 | ||||
|
| ||||
2.3.2. Six filters were placed into separate 4 mL vials and
spiked at each loading of 0.193 mg (0.429 ppm), 0.96 mg (2.13 ppm),
1.93 mg (4.29 ppm), and 4.00 mg (8.88 ppm) catechol and allowed to
equilibrate overnight at room temperature. They were extracted with
3 mL of the desorbing solution for 30 minutes with occasional
shaking, and were analyzed by
Table 2
Desorption Efficiency
|
| ||||
| Filter | % Recovered | |||
| # | 0.193 mg | 0.96 mg | 1.93 mg | 4.00 mg |
|
| ||||
| 1 | 100 | 102 | 98.7 | 98.6 |
| 2 | 100 | 99.3 | 100 | 98.9 |
| 3 | 99.8 | 99.9 | 101 | 99.9 |
| 4 | 102 | 99.8 | 101 | 99.9 |
| 5 | 101 | 99.9 | 101 | 99.4 |
| 6 | 98.0 | 100 | 99.7 | 99.9 |
| average | 100 | 100 | 100 | 99.6 |
| overall average 100 | ||||
| standard deviation ± 0.998 | ||||
|
| ||||
2.4. Retention efficiency
The filters of six OVS-7 tubes were spiked with 2.0 mg (4.44 ppm)
catechol, allowed to equilibrate overnight and then had 100 liters
humid air (91% RH) pulled through them. The glass fiber filter was
placed before the Teflon spacer to insure that no catechol spiked onto
the filter was in contact with the
Table 3
Retention Efficiency
|
| ||||
| Tube # | % Recovered | % Recovered | % Recovered | Total |
| Filter | 'A' | 'B' | ||
|
| ||||
| 1 | 85.9 | 14.0 | 0.0 | 99.9 |
| 2 | 83.7 | 14.2 | 0.0 | 97.9 |
| 3 | 75.5 | 20.8 | 0.0 | 96.3 |
| 4 | 84.1 | 15.9 | 0.0 | 100 |
| 5 | 78.0 | 20.6 | 0.0 | 98.6 |
| 6 | 83.8 | 15.3 | 0.0 | 99.1 |
| average | 98.6 | |||
|
| ||||
2.5. Storage
Glass fiber filters(GFF) from the OVS-7 tubes were removed and
spiked with 2.23 mg (4.95 ppm) catechol and placed in a 4 mL vial
containing the front section of
Table 4
Storage Study
|
| ||||||
| Day | % Recovered Light | % Recovered Dark | ||||
| GFF | XAD-7 | Total | GFF | XAD-7 | Total | |
|
| ||||||
| 7 | 26.7 | 72.6 | 99.3 | 33.7 | 65.3 | 99.0 |
| 7 | 58.3 | 41.6 | 99.9 | 44.4 | 54.7 | 99.1 |
| 7 | 45.4 | 53.1 | 98.5 | 49.5 | 48.8 | 98.3 |
| 14 | 0.3 | 98.2 | 98.5 | 24.3 | 74.6 | 98.9 |
| 14 | 1.4 | 97.6 | 99.0 | 22.6 | 74.1 | 96.7 |
| 14 | 20.4 | 76.6 | 97.0 | 1.0 | 97.5 | 98.5 |
| Average | 98.7 | Average | 98.4 | |||
| Overall | Average | 98.6 | ||||
|
| ||||||
2.6. Precision
The precision was calculated using the area counts from six injections of each standard at concentrations of 0.0644 mg/mL (0.429 ppm), 0.320 mg/mL (2.13 ppm), 0.644 mg/mL (4.29 ppm), and 1.33 mg/mL (8.86 ppm) catechol in the desorbing solvent. The pooled coefficient of variation was 0.0105.(Table 5)
Table 5
Precision Study
|
| ||||
| Injection | ||||
| Number | 0.0644mg/mL | 0.320mg/mL | 0.644mg/mL | 1.33mg/mL |
|
| ||||
| 1 | 1740 | 16279 | 42942 | 114630 |
| 2 | 1775 | 16018 | 43672 | 113338 |
| 3 | 1792 | 16124 | 43863 | 112695 |
| 4 | 1788 | 16380 | 43343 | 113710 |
| 5 | 1755 | 16325 | 42926 | 111274 |
| 6 | 1791 | 16165 | 43275 | 111157 |
| Average | 1774 | 16215 | 43337 | 112801 |
| Standard | ± 21.6 | 136 | 379 | 1379 |
| Deviation | ||||
| CV | 0.0122 | 0.00839 | 0.00875 | 0.0122 |
| Pooled CV | 0.0105 | |||
|
| ||||
where:
CVl, CV2, CV3, CV4 = Coefficients at each level
2.7. Air volume and sampling rate studied
- 2.7.1. The air volume studied is 100 liters.
2.7.2. The sampling rate studied is 1 liter per minute.
2.8. Interferences
Suspected interferences should be listed on sample data sheets.
2.9. Safety precautions
- 2.9.1. Sampling equipment should be placed on an employee in a
manner that does not interfere with work performance or safety
2.9.2. Safety glasses should be worn at all times in designated areas.
2.9.3. Follow all safety practices that apply to the workplace being sampled.
3. Analytical method
- 3.1. Apparatus
- 3.1.1. Gas chromatograph equipped with a flame ionization
detector. A HP 5890 gas chromatograph was used in this study.
3.1.2. GC column capable of separating the analyte and an internal standard from any interferences. The column used in this study was a 15 meter DB-WAX capillary column 0.25µ d.f., 0.32mm I.D.
3.1.3. An electronic integrator or some other suitable method of measuring peak areas.
3.1.4. Two and four milliliter vials with Teflon-lined caps.
3.1.5. A 10 µL syringe or other convenient size for sample injection.
3.1.6. Pipettes for dispensing the desorbing solution. The Glenco 1 mL dispenser was used in this method.
3.1.7. Volumetric flasks - 5 mL and other convenient sizes for preparing standards.
3.1.8. An analytical balance capable of weighing to the nearest 0.01 mg.
3.2 Reagents
- 3.2.1. Purified GC grade nitrogen, hydrogen, and air.
3.2.2. Catechol, Reagent grade
3.2.3. Methanol, HPLC grade
3.2.4. Dimethyl formamide, Reagent grade
3.2.5. The desorbing solution is 0.25 µL/mL dimethyl formamide in methanol.
3.3. Sample preparation
- 3.3.1. Sample tubes are opened and the glass fiber filter and
the front and back section of each tube are placed in separate 4 mL
vials.
3.3.2. Each section is desorbed with 3 mL of the desorbing solution.
3.3.3. The vials are sealed immediately and allowed to desorb for 30 minutes on a shaker, a roto-rack, or a sample rocker.
3.3.4. Samples were transfered to two milliliter vials for anaylsis, as this was the size needed to fit in the autosampler.
3.4. Standard preparation
- 3.4.1. Standards are prepared by diluting a known quantity of
catechol with the desorbing solution.
3.4.2. At least two separate stock standards should be made. Dilutions of the stock standards are prepared covering the concentrations in the samples. The analytical standards used in this study ranged from 0.001 to 1.33 mg/mL of catechol the desorbing solution.
3.5. Analysis
- 3.5.1. Gas chromatograph conditions.
| Flow rates (mL/min) | Temperature (°C) | ||
| Nitrogen(makeup) | : 30 | Injector | : 220 |
| Hydrogen(carrier) | : 1.5 | Detector | : 250 |
| Air | : 450 | Column | : 90°-1 min |
| Hydrogen(detector) | : 60 | 15°C/min-220°C | |
| Injection size | : l µL | ||
| Elution time | : 8.912 min | ||
| Chromatogram | :(See Figure 2) | ||
3.5.2. Peak areas are measured by an integrator or other suitable means.
3.6. Interferences (analytical)
- 3.6.1. Any compound having the general retention time of the
analyte or the internal standard used is an interference. Possible
interferences should be listed on the sample data sheet. GC
parameters should be adjusted if necessary so these interferences
will pose no problems.
3.6.2. Retention time data on a single column is not considered proof of chemical identity. Samples over the target concentration should be confirmed by GC/Mass Spec or other suitable means.
3.7. Calculations
- 3.7.1. A curve with area counts versus concentration is
calculated from the calibration standards.
3.7.2. The area counts for the samples are plotted with the calibration curve to obtain the concentration of catechol in solution.
3.7.3. To calculate the concentration of analyte in the air sample the following formulas are used:
| (µg/m)(desorption volume)
(desorption efficiency) |
= mass of analyte in sample |
| (mass of analyte in sample)
molecular weight |
= number of moles of analyte |
| (number of moles of analyte) | (molar volume at 25°C & 760mm) | = | volume the analyte will occupy at 25°C & 760mm |
| (volume analyte
occupies)(106)
(air volume) |
= ppm |
* All units must cancel.
3.7.4. The above equations can be consolidated to form the following formula. To calculate the ppm of analyte in the sample based on a 100 liter air sample:
| (µg/mL)(DV)(24.45)(106)
(100 L)(DE)(MW) |
× | (g)
(1000 mg) |
× | (mg)
(1000 µg) |
= ppm |
| µg/mL | = concentration of analyte in sample or standard |
| 24.45 | = Molar volume (liters/mole) at 25 °C and 760 mm Hg. |
| MW | = Molecular weight (g/mole) |
| DV | = Desorption volume of 3 mL |
| 100 L | = 100 liter air sample |
| DE | = Desorption efficiency |
3.7.5. This calculation is done for each section of the sampling tube and the results added together.
3.8. Safety precautions
3.8.1. All handling of solvents should be done in a hood.
3.8.2. Avoid skin contact with all chemicals.
3.8.3. Wear safety glasses, gloves and a lab coat at all times.
4. Recommendations for further study
Collection studies need to be performed.
Figure 1. A diagram of an OVS-7 tube. 
with 0.25 µL/mL dimethyl formamide internal standard.
5. References
- 5.1. Cummins,K., Method 32, "Phenol and Cresol", Organic Methods
Evaluation Branch, OSHA Salt Lake Technical Center, 1986.
5.2. Windholz, M., "The Merck Index", Eleventh Edition, Merck & Co., Rahway N.J., 1989, p.1272.
5.3. "Documentation of the Threshold Limit Values and Biological Exposure Indices", Fifth Edition, American Conference of Governmental Industrial Hygienists Inc., Cincinnati, OH, 1986, p. 112.
