1. General Discussion
1.1 Background
1.1.1 History of
procedure
The OSHA Laboratory recently received
samples collected on charcoal tubes requesting analysis for ethyl
methacrylate. A desorption study using carbon disulfide as the
desorbing solvent showed a 92.8% recovery. The other analytes
requested on the samples could not be desorbed with carbon disulfide.
Other desorbing solvents tried were 1:99 dimethyl formamide:carbon
disulfide (97.4% desorption efficiency) and 5:95
methanol:methylene chloride (98.5% desorption efficiency). The
retention studies gave 100% recovery. The storage study for 14 days
averaged 98.3% recovery.
1.1.2 Toxic Effects (Ref. 5.1)
(This section is for information purposes and should not be taken
as the basis for OSHA policy.)
Ethyl methacrylate causes
irritation to mucous membranes in high concentrations. Ethyl
methacrylate in high concentrations is a
teratogen.
1.1.3 Potential workplace exposure
(Ref. 5.2)
Ethyl methacrylate is used in the manufacture of
resins, polymers, fake nails, and contact lens.
1.1.4
Physical properties: (Ref. 5.3)
Synonyms:
|
Methacrylic acid, ethyl ester; ethyl 2-methylacrylate;
ethyl 2-methyl-2-propenoate; Rhoplex AC-33; 2-propenoic
acid, 2-methyl-ethyl ester. |
| Structure: |
 |
Molecular weight:
Density:
Freezing
point:
Boiling point:
Odor:
Color:
Molecular
formula:
Flash
point:
CAS:
IMIS:
RTECS: |
114.14
0.9135
-75°C
117°C
acrylate
odor
clear or light yellow
liquid
C6H10O2
21°C
(70°F)
97-63-2
E115
47787 (OZ
4550000) | 1.2 Limit defining parameters
1.2.1 The detection limit of the
analytical procedure is 1 µg ethyl methacrylate. This is the
smallest amount that could be detected under normal operating
conditions. 1.2.2 The overall detection limit is 0.02 ppm based
on a 10 liter air volume. All ppm amounts in this study will be based
on a 10 liter air volume. 1.3 Advantages
1.3.1 The sampling procedure is
convenient.
1.3.2 The analytical method is
reproducible and sensitive.
1.3.3 Re-analysis 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 found. 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 Coconut shell
charcoal tubes, lot 120, containing a 100 mg adsorbing section with a
50 mg backup section separated by a 2 mm portion of urethane foam,
with a silane-treated glass wool plug before the adsorbing section and
a 3 mm plug of urethane foam at the back of the backup section.
The ends are flame sealed and the glass tube containing the adsorbent
is 7 cm long, with a 6 mm O.D. and 4 mm I.D., SKC tubes or
equivalent. 2.2
Sampling technique
2.2.1 The ends of the charcoal
tube are opened immediately before sampling.
2.2.2
Connect the charcoal tube to the sampling pump with flexible
tubing.
2.2.3 Tubes should be placed in a vertical
position to minimize channeling, with the smaller section towards the
pump.
2.2.4 Air being sampled should not pass
through any hose or tubing before entering the charcoal
tube.
2.2.5 Seal the charcoal tube with plastic
caps immediately after sampling. Seal each sample lengthwise with OSHA
Form-21 sealing tape.
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 the
samples. 2.3 Desorption and/or Extraction
efficiency
2.3.1 The desorption study of
ethyl methacrylate with 1 mL carbon disulfide standard was performed
by liquid spiking six charcoal tubes at each of the following levels;
0.4568 mg (9.79 ppm), 2.284 mg (48.9 ppm), and 4.568 mg (97.9 ppm).
The tubes were allowed to equilibrate overnight at room temperature.
They were opened, each section placed into separate 2 mL vials and
desorbed with 1 mL carbon disulfide, for 30 minutes with occasional
shaking. They were analyzed by GC-FID. The desorption efficiency was
92.8% (Table 2.3.1).
Table 2.3.1
|
Carbon Disulfide Desorption Study
%
Desorption |
|
| Tube # |
0.4568
mg |
2.284 mg |
4.568
mg |
|
| 1 |
89.1 |
94.7 |
94.6 |
| 2 |
88.3 |
94.3 |
94.4 |
| 3 |
88.8 |
94.1 |
93.6 |
| 4 |
89.5 |
94.2 |
94.3 |
| 5 |
89.4 |
93.9 |
93.9 |
| 6 |
89.5 |
99.6 |
94.4 |
| Average |
89.1 |
95.1 |
94.1 |
| Overall Average 92.8 |
| Standard Deviation ±2.98 |
| 2.3.2 The
desorption efficiency using 1:99 dimethyl formamide: carbon disulfide
was performed by liquid spiking six tubes with ethyl methacrylate
at the following levels (equivalent air concentrations) of 0.4568 mg
(9.79 ppm), 2.284 mg (48.9 ppm), and 4.568 mg (97.9 ppm). The samples
were stored overnight at room temperature. They were opened, each
section placed into a separate 2 mL vial, desorbed with 1 mL desorbing
solvent for 30 minutes with occasional shaking and analyzed by GC-FID.
The desorption efficiency averaged 97.4% (Table
2.3.2).
Table 2.3.2
|
1:99 Dimethyl Formamide: Carbon
Disulfide
Desorption Study
% Desorption |
|
| Tube # |
0.14568
mg |
2.284 mg |
4.568
mg |
|
| 1 |
97.9 |
96.0 |
97.1 |
| 2 |
98.2 |
96.0 |
97.3 |
| 3 |
97.3 |
96.4 |
97.3 |
| 4 |
99.3 |
97.4 |
97.7 |
| 5 |
96.9 |
96.8 |
97.8 |
| 6 |
98.4 |
96.6 |
98.2 |
| Average |
98.0 |
96.5 |
97.6 |
| Overall Average 97.4 |
| Standard Deviation ±0.855 |
|
2.3.3 The desorption study using
5:95 methanol: methylene chloride was performed by liquid spiking six
charcoal tubes with ethyl methacrylate at the following levels
(equivalent air concentration), 0.4568 mg (9.79 ppm), 2.284 mg (48.9
ppm), 4.568 mg (97.9 ppm), and 9.135 mg (196 ppm). The tubes were
allowed to equilibrate at room temperature overnight. They were
opened, each section placed into a separate 2 mL vial, and desorbed
with 1 mL of the desorbing solution for 30 minutes with occasional
shaking, and analyzed by GC-FID. The desorption efficiency averaged
98.5% (Table 2.3.3).
Table 2.3.3
|
5:95
Methanol: Methylene Chloride Desorption Study
%
Desorption |
|
| Tube # |
0.457 mg |
2.28 mg |
4.57 mg |
9.14 mg |
|
| 1 |
98.0 |
100 |
96.8 |
100 |
| 2 |
99.7 |
96.5 |
97.7 |
100 |
| 3 |
96.4 |
100 |
95.6 |
100 |
| 4 |
100 |
96.5 |
99.5 |
100 |
| 5 |
99.5 |
100 |
96.4 |
99.8 |
| 6 |
95.9 |
lost |
95.3 |
100 |
| Average |
98.3 |
98.7 |
96.9 |
100 |
| Overall
Average 98.5 |
| Standard
Deviation ±1.79 |
|
2.4
Retention efficiency
The
retention efficiency was performed by spiking six tubes with 4.568 mg
(97.9 ppm) ethyl methacrylate, and drawing 10 liters of humid air (94%
RH) through them. They were opened, desorbed with 1 mL desorbing
solution, and analyzed by GC-FID. The amounts in Table 2.4 are
desorption corrected and the average recovery was 102%.
Table 2.4
|
| Retention
Efficiency |
|
| 1 |
104 |
ND |
104 |
| 2 |
105 |
ND |
105 |
| 3 |
101 |
ND |
101 |
| 4 |
102 |
ND |
102 |
| 5 |
101 |
ND |
101 |
| 6 |
102 |
ND |
102 |
|
|
Average |
102 |
|
2.5
Storage
Six charcoal tubes
were spiked with 4.568 mg (97.9 ppm) and stored at room
temperature. Three of these tubes were analyzed at 6 and 14 days after
spiking. The amounts reported are desorption corrected. The average
recovery was 99.7% (Table 2.5).
Table 2.5
|
| Storage Study |
|
| Days
Stored |
%
Recovered |
|
| 6 |
100 |
| 6 |
100 |
| 6 |
101 |
| 14 |
99.1 |
| 14 |
98.6 |
| 14 |
99.6 |
|
Average
99.7 |
|
2.6
Precision
The precision was
determined by six injections of standard at concentrations of
0.4568 mg/mL (9.79 ppm), 2.284 mg/mL (48.9 ppm), 4.568 mg/mL (97.9
ppm), and 9.135 mg/mL (196 ppm) (Table 2.6).
Table 2.6
|
| Precision of the Analytical Procedure |
|
| Injection
Number |
0.4568
mg/mL |
2.284
mg/mL |
4.568
mg/mL |
9.135
mg/mL |
| 1 |
498338 |
2444481 |
4974609 |
9745276 |
| 2 |
493750 |
2448606 |
4968818 |
9755312 |
| 3 |
492081 |
2479016 |
4940095 |
9774749 |
| 4 |
497300 |
2480853 |
4925562 |
9732824 |
| 5 |
498060 |
2476000 |
4980306 |
9718711 |
| 6 |
497177 |
2483968 |
4942801 |
9719335 |
| Average |
496118 |
2468821 |
4955365 |
9741035 |
| Standard
Deviation |
±2574 |
±17497 |
±22849 |
±21887 |
| CV |
0.00519 |
0.00709 |
0.00461 |
0.00225 |
| Pooled CV |
0.00519 |
|
|
|
| A(1), A(2), A(3), A(4)
= # of injections at each level
CV1, CV2, CV3, CV4 =
Coefficients at each level 2.7 Air volume and sampling rate studied
2.7.1 The air volume studied was 10
liters.
2.7.2 The sampling rate studied was 0.2
liters 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.
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.
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 12 ft stainless steel column packed with 10% FFAP on 80/100 mesh
Chrom WAW.
3.1.3 An electronic integrator or some
other suitable method of measuring peak
areas.
3.1.4 Two milliliter vials with Teflon-lined
caps.
3.1.5 A 10-µL syringe or other convenient
size for sample injection.
3.1.6 Pipets for
dispensing the desorbing solution. The Glenco 1 mL dispenser was used
in this evaluation.
3.1.7 Volumetric flasks - 5 mL
and other convenient sizes for preparing standards.
3.2 Reagents
3.2.1 Purified GC grade
nitrogen, hydrogen, and air.
3.2.2 Ethyl
Methacrylate, Reagent grade 3.2.3 Carbon Disulfide,
Reagent grade
3.2.4 Internal Standard (p-Cymene)
Reagent grade
3.2.5 Desorbing solution contains 1
µL/mL p-cymene in carbon
disulfide.
3.3 Sample preparation
3.3.1 Sample tubes are opened
and the front and back section of each tube are placed in
separate 2 mL vials.
3.3.2 Each section is desorbed
with 1 mL of carbon disulfide with 1 µL/mL p-cymene internal
standard.
3.3.3 The vials are sealed immediately
and allowed to desorb for 30 minutes with occasional shaking.
3.4 Standard
preparation
3.4.1 Standards are prepared by
diluting a known quantity of ethyl methacrylate with carbon disulfide
containing 1 µL/mL internal standard. A 1 µl/mL standard of ethyl
methacrylate in the desorbing solution contains 984.4 µg/mL (21.09
ppm) corrected for the desorption efficiency of
92.8%.
3.4.2 At least two separate standards should
be made.
3.4.3 A third standard at a higher
concentration should be prepared to check the linearity of the
analysis. This third standard is at 4 µL/mL. 3.5 Analysis
3.5.1 Gas chromatograph
conditions.
| Flow Rates (mL/min) |
Temperature (ºC) |
|
| Nitrogen (carrier):
29 |
Injector: 180 |
| Hydrogen: 40 |
Detector: 220 |
| Air: 240 |
Column: 80ºC, hold 4
min ramp at 10ºC/min to 140ºC |
| Injection Size: |
1 µL |
| Elution time: |
2.56 min |
| Chromatogram: |
 | 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 The integrator is
calibrated with two standards at the same concentration, and the
linearity of the analysis is checked with the third
standard.
3.7.2 To calculate the air concentration
of analyte in the sample, the following formulas are
used:
3.7.3 The above equations can be consolidated to
form the following formula. To calculate the ppm of analyte in the
sample based on a 5 liter air sample:
| µg/mL |
= |
concentration of
analyte in sample or standard |
| 24.46 |
= |
Molar volume
(liters/mole) at 25°C and 760 mmHg |
| MW |
= |
Molecular weight
(g/mole) |
| DV |
= |
Desorption volume |
| 5 L |
= |
5 liter air
sample |
| DE |
= |
Desorption
efficiency |
3.7.4 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 solvents.
3.8.3 Wear safety
glasses at all times. 4. Recommendations for further study: Collection studies for
ethyl methacrylate need to be performed.
5.
References
5.1 Sweet, D., "Registry of Toxic
Effects of Chemical Substances," 1985-86 edition, U.S. Department of
Health and Human Services, Public Health Service, Center for Disease
Control, NIOSH, 1987, Vol. 3A, p. 3060-101.
5.2 Hawley, G.,
"The Condensed Chemical Dictionary", Van Nostrand Reinhold Co. New York,
N.Y. Tenth Edition, 1981, p. 440.
5.3 Weast, R.C.,
Grasselli, J.G., "Handbook of Data on Organic Compounds", CRC Press,
Inc. Boca Raton, FL. 2nd Edition, 1985, page 3810.
|
Back
to Top 
http://www.osha-slc.gov/
