Dimethyl adipate

Administrative data

Link to relevant study record(s)

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Reference 1

Endpoint:

biodegradation in water: screening tests

Type of information:

read-across based on grouping of substances (category approach)

Adequacy of study:

supporting study

Study period:

1982-05-04 to 1982-10-13

Reliability:

2 (reliable with restrictions)

Rationale for reliability incl. deficiencies:

other: Valid and conclusive guideline study, non-GLP

Justification for type of information:

This IUCLID for dimethyl adipate is compiled using data from the substance itself, a structurally related compound (dimethyl glutarate) and a mixture of dibasic esters (dimethyl adipate, succinate and glutarate). The toxicity of each of these substances is similar and the document attached justifies why data on the category members can be used to support the data gaps for dimethyl adipate.

Qualifier:

according to guideline

Guideline:

EPA OPPTS 835.3170 (Shake Flask Die-away Test)

Version / remarks:

Federal Register 44(53):16272-16285, March 16, 1979

Deviations:

yes

Remarks:

- with regard to recent (1998) standards e.g. different inoculum, incubation at 100 rpm only, no substance specific analytics (primary degradation not investigated), no equilibrium sorption coeffifient investigated

Principles of method if other than guideline:

The procedure selected for this study was the aerobic shake flask method as suggested by the United States Environmental Protection Agency. The method involved two phases: an acclimation period of 13 days during which the mixed microbial inoculum adapted or acclimated to the test substances; the second phase was a 28-day test period during which measurements were taken of the respired Carbondoxide and, if possible, subsamples were removed for the determination of the changes in the substrate concentrations.
Also, pH, temperature and dissolved oxygen were measured to assure adequate incubation conditions.

GLP compliance:

no

Oxygen conditions:

aerobic

Inoculum or test system:

other: Adapted composite of three sources mixed 4:2:1: sewage, domestic (adaptation not specified) : natural soil : digested sludge

Details on inoculum:

The inoculum was a composite of three sources mixed together at a ratio of 4:2:1, respectively.
(1) Sewage, domestic (adaptation not specified): The primary component was obtained from the Wilmington, Delaware, U.S.A. secondary waste treatment facility. Freshly collected sludge was filtered through a glass wool pad
(2) Natural soil: The soil was collected in the woods around Haskell Laboratory, Newark, Delaware 19711, U.S.A. and 300 g soil was suspended in 3 L chlorine-free water. The soil suspension was stirred for 1-1½ hours, allowed to settle for 1 hour and then filtered.
(3) Digested sludge: A third component of the inoculum was the continuously mixed microbial culture maintained for over 2 years in a biological digestor system (Horizon Activated Sludge Percolator) at Haskell Laboratory. The original source for this mixed community was a soil and sludge mixture.

Acclimation period: The basal medium was dispensed in 100 mL aliquots into 250 mL sterile plastics crew-cap erlenmeyer flasks and autoclaved. After cooling, the yeast extract was added. Transfers were made every 48 to 72 hours to fresh medium containing the same constituents. After inoculation with 1.0 mL of the prepared inoculum, the flasks were incubated on a gyrorotary water bath shaker at 25° C at a shaker setting of 3-3¾. The flasks were kept in the dark to prevent photodegradation of the test compounds and /or growth of photosynthetic microorganisms.

Duration of test (contact time):

28 d

Initial conc.:

5 mg/L

Based on:

DOC

Initial conc.:

10 mg/L

Based on:

DOC

Parameter followed for biodegradation estimation:

CO2 evolution

Details on study design:

Test Period:
On the 13th day following the initial inoculation of the acclimation flasks, and 48 to 72 hours after the last transfer, 10 mL aliquots were transferred to 1 L erlenmeyer flasks containing 500 mL of the appropriate medium.

TEST CONDITIONS
- Composition of medium: The basal medium, which contained no added organic carbon substrate, was composed of a phosphate buffer solution, NH4Cl, MgSO4, CaC12, FeCl3, a trace element solution, yeast extract, and ASTM Type II water.
- Additional substrate: no
- Test temperature: 22-23 °C
- pH: 5.4-6.9
- pH adjusted: no
- Continuous darkness: yes
- Other: Dissolved oxygen 4.0 to 6.5 mg/L; every third sampling period, 90 mL of sterile ASTM Type II water was added to each flask to maintain the proper liquid level.

TEST SYSTEM
- Culturing apparatus: All flasks were incubated on a gyrorotary shaker set at 100 rpm
- Number of culture flasks/concentration: 2, all flasks were prepared in duplicate.
- Method used to create aerobic conditions: The flasks were specially designed to allow filtered air to enter through an ascarite-glass wool plug.
- Measuring equipment: Dissolved oxygen (DO) was measured with a Dissolved Oxygen Meter and probe (Yellow Springs Instruments), the pH was taken with a combination electrode coupled to an Orion pH Meter; and the temperature was read from mercury thermometers in the room.
- Test performed in open system: yes
- Details of trap for CO2 and volatile organics if used: The flasks were specially designed an had a side arm on which replaceable CO2 traps could be attached. On each sampling day, the KOH-containing bottle, attached to the side arm of each rest flask to trap respired CO2, was removed. A fresh bottle containing 2 mL of standard KOH was immediately replaced on the side arm of each 1 L Erlenmeyer flask. In order to assure aerobic conditions, all stopcocks were opened during the sampling periods (approximately 2 hours) and closed throughout the rest of the incubation period.


SAMPLING
- Sampling frequency: on days 1, 2, 5, 7, 9, 14, 16, 21, 24, 28
- Sampling method: The flasks were specially designed and had a sterile sampling port. On each subsequent sampling day, 30 mL were withdrawn from the sampling port: 10 mL were fixed in 30% formaldehyde and 20 mL were filtered through boiled Nuclepore® filters to remove the microbial cells.
- Sample storage before analysis: The filtrates were frozen.

CONTROL AND BLANK SYSTEM
- Inoculum blank: no
- Abiotic sterile control: yes
- Toxicity control: no
- Other:
The organic amendments to the basal medium were:
- test compound at nominal 5 or 10 mg organic carbon/L basal medium;
- a known biodegradable substance, linear alkylate sulfonates (LAS), at a nominal 5 or 10 mg organic carbon/L basal medium;
- a control flask containing only basal medium;
- a control flask which contained the high concentration of all organic substances but no deliberate inoculum;
- another control flask which contained a reference material which is only partially biodegradable, benzisothiazolin-3-one (in Proxel®, active ingredient BIT), also at nominal 5 or 10 mg organic carbon/L basal medium.


STATISTICAL METHODS:
- Outliner elimination: After titration of the samples, an additional 2 to 3 blanks were also titrated. The blanks were averaged and values not within 5% of the mean were discarded.

Reference substance:

other: known biodegradable substance: LAS (CAS 42615-29-2), linear alkylate sulfonates

Reference substance:

other: material which is only partially biodegradable: benzisothiazolin-3-one (in Proxel®, active ingredient BIT)

Parameter:

% degradation (CO2 evolution)

Value:

36

Sampling time:

21 d

Remarks on result:

other: 36% of the theoretical cumulative percent CO2 was respired by the mixed microbial system

Details on results:

Figure 1 (illustration attached) depicts the amount of carbon dioxide produced from the Dibasic Esters at nominal concentrations of 5 and 10 mg C/L. The data have been corrected for the carbon dioxide respired in the control flasks. The maximum rate of carbon dioxide respiration was achieved for the low concentration between days 1 and 2. Then there appeared to be a very slightly increased level of carbon dioxide production throughout the remainder of the study period. Maximal degradation of DBE at the higher concentration, however, continued throughout the first seven days following inoculation.
Based upon the respiration rates shown in Figure 1 (illustration attached) for the DBE, LAS and Proxel®, half-life for carbon dioxide production from DBE can be calculated (Lehinger 1975). At the high concentration of DBE the rate is 2.5 days while at the lower concentration the half-life rate is 3.2 days.
- Lehinger AL (1975). Biochemistry, 6th ed. Worth Publishers, Inc.

Results with reference substance:

Respiration from LAS degradation did not appear to be important until about day 15 (Figure 1, illustration attached); but from Figure 2 (in study report), it is apparent that the LAS was being consumed by the microbial population. This difference is most likely the result of the microflora incorporating the LAS carbon into microbial biomass. 36% of the theoretical carbon dioxide that could be respired was produced from the DBE supplied to the cultures while only 6 to 15% of the LAS were respired, and for Proxel® the respiration values were 20-21% (Figure 3, illustration attached). The changes in the amount of Proxel® present in the inoculated and control flasks are shown in Figure 4 (in study report).

Validity criteria fulfilled:

yes

Interpretation of results:

inherently biodegradable

Executive summary:

The microbial degradation of Dibasic esters (DBE) was investigated according to the EPA procedures as published in the Federal Register 44(53):16272-16285, March 16, 1979, which is considered similar to EPA OPPTS 835.3170 (Shake Flask Die-away Test). Formal GLP standards did not apply. The study is considered valid and conclusive.

Dibasic esters were subjected to microbiological biodegradation testing using the shake flask method.

The DO (Dissolved oxygen) values throughout the study period ranged from 4.0 t o 6.5 mg/L indicating that an aerobic atmosphere was maintained.

The pH values fluctuated very little during the study staying within a 5.4 t o 6.9 range. These data indicate that environmental factors were not limiting the amount or rate of biodegradation of the various test substances.

The half-life for the high concentration of DBE was 2.5 days while at the low concentration the half-life was 3.2 days. In either case, 36% of the theoretical cumulative percent CO₂ was respired by the mixed microbial system.