Hydrocarbons, C9-C11, n-alkanes, isoalkanes,

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Reference 1

Endpoint:

biodegradation in water: ready biodegradability

Type of information:

experimental study

Adequacy of study:

other information

Study period:

Experimental starting date: 10th July 2014 Experimental completion date: 29th September 2014

Reliability:

1 (reliable without restriction)

Rationale for reliability incl. deficiencies:

guideline study

Remarks:

Study conducted in compliance with agreed protocols, with no or minor deviations from standard test guidelines and/or minor methodological deficiencies, which do not affect the quality of the relevant results.

Qualifier:

according to guideline

Guideline:

OECD Guideline 301 F (Ready Biodegradability: Manometric Respirometry Test)

Deviations:

no

Qualifier:

according to guideline

Guideline:

EU Method C.4-D (Determination of the "Ready" Biodegradability - Manometric Respirometry Test)

Deviations:

no

Qualifier:

according to guideline

Guideline:

EPA OPPTS 835.3110 (Ready Biodegradability)

Deviations:

no

GLP compliance:

yes (incl. QA statement)

Oxygen conditions:

aerobic

Remarks:

E

Inoculum or test system:

sewage, domestic, non-adapted

Details on inoculum:

Test System
A mixed population of sewage treatment micro-organisms was obtained on 20 August 2014 from the final effluent stage of the Severn Trent Water Plc sewage treatment plant at Loughborough, Leicestershire, UK, which treats predominantly domestic sewage.


Preparation of Inoculum
The sample of effluent was filtered through coarse filter paper (first approximate 200 mL discarded) and maintained on aeration in a temperature controlled room at 21 ± 1 ºC prior to use.

FOR A DESCRIPTION OF THE MINERAL MEDIUM, PLEASE REFER TO THE ATTACHED APPENDIX 1

Duration of test (contact time):

28 d

Initial conc.:

100 mg/L

Based on:

test mat.

Parameter followed for biodegradation estimation:

O2 consumption

Remarks:

Daily oxygen consumption

Parameter followed for biodegradation estimation:

test mat. analysis

Details on study design:

Experimental Preparation
Test Item
For the purpose of the test, due to the volatile nature of the test item, at the request of the Sponsor, the test item was added directly to the test vessels using a gas tight syringe.

An amount of test item (70 µL, equivalent to 50 mg of test item determined by preliminary weighings) was dispensed into mineral medium (495 mL) and inoculum (5 mL) to give the test concentration of 100 mg/L. Due to the volatile nature of the test item each vessel was placed immediately on the respirometer after the addition of the inoculum.

A test concentration of 100 mg/L was selected for use in the study following the recommendations of the Test Guideline.

Inoculum control vessels were prepared containing mineral medium (495 mL) and inoculum (5 mL).

Reference Item
A reference item, aniline (C6H5NH2), was used to prepare the procedure control vessels. An initial stock solution of 1000 mg/L was prepared by dissolving the reference item directly in mineral medium with the aid of ultrasonication for approximately 10 minutes. An aliquot (50 mL) of this stock solution was diluted with mineral medium (445 mL) and the inoculum
(5 mL), to give the test concentration of 100 mg/L. The volumetric flask containing the stock solution was inverted several times to ensure homogeneity.

Toxicity Control
A toxicity control, containing the test item and aniline, was prepared in order to assess any toxic effect of the test item on the sewage treatment micro-organisms used in the test.

An amount of test item (70 µL, equivalent to 50 mg of test item determined by preliminary weighings) was dispensed into mineral medium (445 mL) and an aliquot (50 mL) of the
1000 mg/L aniline stock solution (see Section 3.5.1.2) and inoculum (5 mL) to give the test concentration of 100 mg test item/L and 100 mg aniline/L. Due to the volatile nature of the test item each vessel was immediately placed on the respirometer after the addition of the inoculum.

Abiotic Test
A nominal amount of sodium azide (10.00 g) was dissolved in mineral medium with the aid of ultrasonication for approximately 10 minutes and the volume adjusted to 500 mL to give a
20 g/L stock solution.

An amount of test item (70 µL, equivalent to 50 mg of test item determined by preliminary weighings) was dispensed into mineral medium (445 mL) with an aliquot (50 mL) of the 20 g/L sodium azide stock solution and inoculum (5 mL) to give the test concentration of 100 mg test item/L and 2000 mg sodium azide/L. Due to the volatile nature of the test item each vessel was immediately placed on the respirometer after the addition of the inoculum


Preparation of Test System
The following test preparations were prepared and inoculated in 500 mL bottles:

a) Five replicate bottles containing inoculated mineral medium to act as the inoculum control.
b) Two replicate bottles containing inoculated mineral medium and the reference item, aniline, at a concentration of 100 mg/L.
c) Five replicate bottles containing inoculated mineral medium and the test item at a concentration of 100 mg/L.
d) Two replicate bottles containing inoculated mineral medium the reference item, aniline, at a concentration of 100 mg/L and the test item at a concentration of 100 mg/L to act as toxicity control vessels.
e) Four replicates bottles containing the test item at a concentration of 100 mg/L and sodium azide at a concentration of 2000 mg/L to act as abiotic test vessels.

Data from the inoculum control and procedure control vessels was shared with similar concurrent studies.

All vessels were inoculated with the prepared inoculum at a rate of 1% v/v.

On Day 0 the reference item and sodium azide was added (where appropriate) and the pH of all vessels measured using a Hach HQ40d Flexi handheld meter prior to the addition of test item (where appropriate). If necessary the pH values were adjusted to pH 7.4 ± 0.2 using diluted hydrochloric acid or sodium hydroxide solution prior to the addition of the inoculum and test item.

Two of the five inoculum control and test item vessels and two of the four abiotic test vessels were sacrificed for immediate chemical analysis (see Appendix 3). All remaining inoculum control, test item, procedure control, toxicity control and abiotic test vessels were placed in a CES Multi-Channel Aerobic Respirometer.

The system consists of a sample flask sealed by a sensor head/CO2 trap immersed in a temperature controlled water bath. The samples were stirred for the duration of the test with a magnetically coupled stirrer.

As biodegradation progresses, the micro-organisms convert oxygen to carbon dioxide which is absorbed into the ethanolamine solution (50% v/v) causing a net reduction in gas pressure within the sample flask (see Figure 1). The pressure reduction triggers the electrolytic process, generating oxygen and restoring the pressure in the sample flask. The magnitude of the electrolyzing current and the duration of the current is proportional to the amount of oxygen supplied to the micro-organisms. The data generated from the respirometer’s own battery backed memory was collected on the hard disk drive of a non-dedicated computer.

The test was conducted in diffuse light at temperatures of between 23 and 24 ºC.

On Day 28 an assessment of the biological oxygen demand data was made and the most consistent vessels (two inoculum control, one procedure control, two test item, one toxicity control and two abiotic test vessels) chosen for calculating and reporting purposes. The remaining vessels were discarded and are not reported.

The remaining vessels which were not sampled were discarded and are not reported. Additional replicate vessels were prepared and incubated in order that in the event of a leak in the test system a replicate vessel could be discarded without jeopardizing the integrity of the test.

Evaluations
Oxygen Consumption Measurements
The daily Biological Oxygen Demand (BOD) values for the inoculum control, test item, procedure control and the toxicity control are given Table 1.

Physico-chemical Measurements
The temperature of the water bath was recorded daily.

pH Measurements
On Day 0 the pH of each of the test vessels was determined prior to the addition of the inoculum and, where appropriate, the addition of the test item using a Hach HQ40d Flexi handheld meter. The pH values were adjusted where necessary to pH 7.4 ± 0.2 using diluted hydrochloric acid. The required quantity of inoculum and test item, where appropriate, was then added to each vessel.

On Day 28 the pH of the inoculum control and procedure control vessels was determined. Due to the volatile and oily nature of the test item it was considered inappropriate to determine the pH of the vessels containing test item.

Total Viable Counts
In order to confirm that abiotic conditions were present in the abiotic test vessels at the end of the test, total viable counts were performed. An aliquot (100 µL) of sample was dispensed onto a Tryptone Soya Agar (TSA) plate and spread over the plate prior to incubation at approximately 25 ºC for approximately 2 days. After the incubation period, the number of colony forming units (cfu) were determined by direct counting of the colonies on each agar plate.

Compound Specific Analysis
On Day 0, two inoculum control, two abiotic test and two test item vessels were sacrificed for compound specific analysis. On Day 28 chemical analysis of the two inoculum control, two abiotic test and two test item vessels from which the oxygen consumption values were taken was performed.

Data Evaluation
Calculation of Theoretical Oxygen Demand
The Theoretical Oxygen Demand (ThOD) for a compound CcHhClclNnPpSsOoNana was calculated by:

ThOD (NO3)(mgO2/,g) = (16(2c+0.5(h-cl) + 5/2p + 3s + 1/2 na-o))/molecular weight

Percentage Biodegradation
The percentage biodegradation in terms of oxygen consumption was calculated as follows:

% degradation = (BOD B/ThOD) x 100

Where:
BOD = Biological Oxygen Demand of the test item or reference item (mgO2/L)
B = Oxygen consumption in basal mineral medium to which inoculum is added (control) (mgO2/L)
ThOD = Theoretical oxygen demand to completely oxidize the reference and/or test item (mgO2/L)

Reference substance:

aniline

Preliminary study:

Not applicable

Test performance:

Validation Criteria
The mean BOD of the inoculated mineral medium (control) was 53.48 mg O2/L after 28 days and therefore satisfied the validation criterion given in the OECD Test Guidelines.

The difference between extremes of replicate BOD values at the end of the test was less than 20% and therefore satisfied the validation criterion given in the OECD Test Guidelines.

Total Viable Counts
The total viable counts from the abiotic test vessels confirmed that abiotic conditions had been present as the number of total viable counts were very low.

Parameter:

% degradation (O2 consumption)

Value:

73

Sampling time:

28 d

Details on results:

The test item attained 73% biodegradation after 28 days and can therefore be considered to be readily biodegradable. The test item failed to meet the 10-Day window validation criterion, whereby 60% biodegradation must be attained within 10 days of the biodegradation exceeding 10%. However, in accordance with the Revised Introduction to the OECD Guidelines for Testing of Chemicals, (2006), if testing on a complex mixture is performed, and it is anticipated that a sequential biodegradation of the individual structures takes place, then the 10-Day window should not be applied to interpret the results of the test.

The toxicity control attained 69% biodegradation after 14 days and 76% biodegradation after 28 days thereby confirming that the test item was not toxic to the sewage treatment micro-organisms used in the test.
Aniline (procedure control) attained 74% biodegradation after 14 days and 76% biodegradation after 28 days thereby confirming the suitability of the inoculum and test conditions.

Chemical analysis of the 100 mg/L test preparation at 0 hours showed a mean measured concentration of 92% of nominal was obtained. A decline in measured test concentration was observed on Day 28 to less than the limit of quantification (LOQ) of the analytical method employed, which was determined to be 0.26 mg/L (100% loss over the test duration assuming 100% recovery on Day 0).

The losses observed by chemical analysis were higher than those observed by oxygen consumption. This was considered to be due to a combination of volatility of the test item and incorporation of the test item, or degradation products of the test item, into the microbial biomass. In such cases the micro-organisms present utilize carbon originating from the test item to increase their biomass by incorporation the carbon into new cells. This effectively removes the test item from the aqueous phase and hence reduces the apparent biodegradation of the test item as measured by oxygen consumption.

Chemical analysis of the abiotic test vessels on Day 0 showed a mean measured concentration of 90% of nominal was obtained with analysis on Day 28 showed a mean measured concentration of 6% of nominal was obtained. Given the low total viable counts from the abiotic test vessels on Day 28 and the low biological oxygen consumption values from these vessels it was considered that this 93% loss of test item measured by chemical analysis on Day 28 occurred due to the volatile nature of the test item.

Results with reference substance:

Aniline (procedure control) attained 74% biodegradation after 14 days and 76% biodegradation after 28 days thereby confirming the suitability of the inoculum and test conditions.

Definitive Test - Validation of the Analytical Method

Specificity

The biological control samples and an analyzed analytical blank showed no significant interfering response at the retention time of the test item. The standard solutions contained a peak specific for the test item whose area changed accordingly with known concentration, hence the specificity of the method by retention time was confirmed. 

 

 Linearity

The data was found to have a linear correlation within the calibration range of 0 to 265 mg/L. The R² fit of the calibration curve to the data was 0.9987, and was considered to be acceptable.

 

Accuracy (Recovery) and Precision

A set of recovery samples accurately fortified at a relevant concentration of test item was prepared five-fold and analyzed. 

 

The method was considered to be sufficiently accurate and precise for the purposes of this test. The test sample results were not corrected for recovery. 

Limit of Quantification (LOQ)

The limit of quantification (LOQ) was determined by calculating the sample concentration that gave a peak equivalent to ten times the baseline noise. Using this method the LOQ was determined to be 0.26 mg/L.

 

Validity criteria fulfilled:

yes

Interpretation of results:

readily biodegradable

Conclusions:

The test item attained 73% biodegradation after 28 days and can therefore be considered to be readily biodegradable.

Executive summary:

SUMMARY

Introduction

The study was performed to assess the ready biodegradability of the test item in an aerobic aqueous media. The method followed was designed to be compatible with the OECD Guidelines for Testing of Chemicals (1992) No. 301F, “Ready Biodegradability; Manometric Respirometry Test” referenced as method C.4-D of Commission Regulation (EC) No. 440/2008 and US EPA Fate, Transport, and Transformation Test Guidelines OCSPP 835.3110 (Paragraph (q)).

 

Methods…….

The test item at a concentration of 100 mg/L was exposed to sewage treatment micro-organisms with mineral medium in sealed culture vessels in diffuse light at temperatures of between 23 and 24 ºC for 28 days. 

 

The biodegradation of the test item was assessed by the measurement of daily oxygen consumption values and compound specific analyses on Days 0 to 28. Control solutions with inoculum and the reference item, aniline, together with a toxicity control were used for validation purposes.

 

Results…….

The test item attained 73% biodegradation after 28 days and can therefore be considered to be readily biodegradable. 

Chemical analysis of the 100 mg/L test preparation at 0 hours showed a mean measured concentration of 92% of nominal was obtained. A decline in measured test concentration was observed on Day 28 to less than the limit of quantification (LOQ) of the analytical method employed, which was determined to be 0.26 mg/L (100% loss over the test duration assuming 100% recovery on Day 0). 

 

The losses observed by chemical analysis were higher than those observed by oxygen consumption. This was considered to be due to a combination of volatility of the test item and incorporation of the test item, or degradation products of the test item, into the microbial biomass. In such cases the micro-organisms present utilize carbon originating from the test item to increase their biomass by incorporation the carbon into new cells. This effectively removes the test item from the aqueous phase and hence reduces the apparent biodegradation of the test item as measured by oxygen consumption.

 

Chemical analysis of the abiotic test vessels on Day 0 showed a mean measured concentration of 90% of nominal was obtained with analysis on Day 28 showed a mean measured concentration of 6% of nominal was obtained. Given the low total viable counts from the abiotic test vessels on Day 28 and the low biological oxygen consumption values from these vessels it was considered that this 93% loss of test item measured by chemical analysis on Day 28 occurred due to the volatile nature of the test item.