4-bromobenzyl alcohol

Administrative data

Endpoint:

skin sensitisation: in chemico

Type of information:

experimental study

Adequacy of study:

weight of evidence

Study period:

19 October 2017 - 27 October 2017

Reliability:

1 (reliable without restriction)

Rationale for reliability incl. deficiencies:

guideline study

Data source

Materials and methods

Test guidelineopen allclose all

GLP compliance:

yes (incl. QA statement)

Type of study:

direct peptide reactivity assay (DPRA)

Test material

In chemico test system

Details on the study design:

Skin sensitisation (In chemico test system)

Synthetic peptides used:
- cysteine peptide with an amino acid sequence of Ac-RFAACAA, JPT Peptide Technologies GmbH; > 95%; Lot. No.: 260515HS_DWW1115
- lysine peptide with an amino acid sequence of Ac-RFAAKAA, JPT Peptide Technologies GmbH; > 95%; Lot. No.: 120514HSDW_W0517

Controls used:
- Positive control: Cinnamic aldehyde 100 mM in acetonitrile
- Co-elution control: test item or positive control without cysteine or lysine peptide
- Reference controls (RCs): cysteine or lysine peptide in acetonitrile with and without test item; Reference control A was prepared using acetonitrile in order to verify the accuracy of the calibration curve for peptide quantification. Its replicates were injected in the beginning of each HPLC run. Reference control B was prepared using acetonitrile in order to verify the stability of the respective peptide over the analysis time. Its replicates were injected in the beginning and in the end of each HPLC run. Reference control C was set up for the test item and the positive control. RC C for the positive control was prepared using acetonitrile. RC C for the test item was prepared using the respective solvent used to solubilise the test item. The RC C was used to verify that the solvent does not impact the percent peptide depletion (PPD). Additionally reference control C was used to calculate PPD. The RC C was included in every assay run for both peptides and was injected together with the samples.

Test substance preparation:
- The test substance was prepared as a 100 mM preparation in acetonitrile.

Peptide stock solution preparation:
- 22.31 mg cysteine peptide with an amino acid sequence of Ac-RFAACAA were pre-weighed in a vial and dissolved in a defined volume (41.27 mL) of a phosphate buffer with pH 7.5 to reach a concentration of 0.667 mM.
- 21.3 mg lysine peptide with an amino acid sequence of Ac-RFAAKAA were pre-weighed in a vial and dissolved in a defined volume of ammonium acetate buffer with pH 10.2 (39.76 mL) to reach a concentration of 0.667 mM.

Experimental procedure:
The test item solutions were incubated with the cysteine and lysine peptide solutions in glass vials using defined ratios of peptide to test item (1:10 cysteine peptide, 1:50 lysine peptide). The reaction solutions were left in the dark at 25 ± 2.5 °C for 24 ± 2 h before running the HPLC analysis. Reference controls, co-elution controls as well as the positive control were set up in parallel. Test item solutions were inspected on a visual basis for the formation of precipitates, turbidity and phase separation prior and after HPLC analysis, if a precipitate or phase separation was observed after the reaction period and prior to the HPLC analysis, samples might have been centrifuged at low speed (100 -400x g) to force precipitates to the bottom of the vial. After the incubation period of 24 ± 2 h the test item was analysed in triplicate for both peptides via HPLC.

HPLC conditions:
Peptide depletion was monitored by HPLC coupled with an UV detector at A = 220 nm using a reversed-phase HPLC column (Zorbax SB-C-18 2.1 mm x 100 mm x 3.5 micron) as preferred column. The entire system was equilibrated at 30 °C with 50% phase A (0.1% ( v/v) trifluoroacetic acid in water) and 50% phase B (0.085% ( v/v) trifluoroacetic acid in acetonitrile) for at least 2 hours before running the analysis sequence. The HPLC analysis was performed using a flow rate of 0.35 mL/min and a linear gradient from 10% to 25% acetonitrile over 10 minutes, followed by a rapid increase to 90% acetonitrile. The column was re-equilibrated under initial conditions for 7 minutes between injections. Equal volumes of each standard, sample and control were injected. HPLC analysis for the cysteine and lysine peptide was performed concurrently (if two HPLC systems were available) or on separate days. If analysis was conducted on separate days all test chemical solutions were freshly prepared for both assays on each day.
The analysis was timed to assure that the injection of the first sample started 22 to 26 hours after the test chemical was mixed with the peptide solution. The HPLC run sequence was set up in order to keep the HPLC analysis time less than 30 hours.

Calculation and data evaluation:
The concentration of the cysteine and lysine peptide was determined in each sample from absorbance at A = 220 nm, measuring the area of the appropriated peaks (peak area (PA)) and calculating the concentration of peptide using the linear calibration curves derived from the standard solutions.
PPD = (1 - (Peptide Peak Area in the Replicate Injection / Mean Peptide Peak Area in Reference Control C)) * 100
Sensitising potential of the test item is predicted from the mean cysteine and lysine PPD value. The test item is considered positive to be a skin sensitiser in accordance with UN GHS "Category 1", if the mean depletion of both peptides exceeds the threshold of the respective prediction model. Negative depletion is considered as "0" when calculating the mean. Sensitizing potential might not be predictable if the test item was incubated using a concentration differently from 100 mM.
By using the prediction model 1 (cysteine 1:10 / lysine 1:50 prediction model) the threshold of 6.38% average peptide depletion was used to support the discrimination between skin sensitisers and non-sensitisers.
By using the prediction model 2 (cysteine 1:10 prediction model) the threshold of 13.89% peptide depletion was used to support the discrimination between skin sensitisers and non-sensitisers.

Acceptance criteria:
The run meets the acceptance criteria if:
- the standard calibration curve has a r2 > 0.99,
- the mean percent peptide depletion (PPD) value of the three replicates for the positive control is between 60.8% and 100% for the cysteine peptide and the maximum standard deviation (SD) for the positive control replicates is < 14.9%,
- the mean percent peptide depletion (PPD) value of the three replicates for the positive control is between 40.2% and 69.0% for the lysine peptide and the maximum SD for the positive control replicates is < 11.6%,
- the mean peptide concentration of the three reference controls A replicates is 0.50 ± 0.05 mM,
- the coefficient of variation (CV) of peptide peak areas for the six reference control B replicates and three reference control C replicates in acetonitrile is < 15.0%.
The results of the test item meet the acceptance criteria if:
- the maximum standard deviation (SD) for the test chemical replicates is < 14.9% for the cysteine percent depletion (PPD),
- the maximum standard deviation (SD) for the test chemical replicates is < 11.6% for the lysine percent depletion (PPD),
- the mean peptide concentration of the three reference controls C replicates in the appropriate solvent is 0.50 ± 0.05 mM.

Results and discussion

Positive control results:

The 100 mM stock solution of the positive control (cinnamic aldehyde) showed high reactivity towards the synthetic peptides. The mean depletion of both peptides was 66.16%.

In vitro / in chemico

Resultsopen allclose all

Other effects / acceptance of results:

OTHER EFFECTS:
- Visible damage on test system: Precipitation and phase seperation was observed for the positive control samples. Since the acceptance criteria for the depletion range of the positive control were fulfilled, the observed precipitations and phase separation were regarded as insignificant.

ACCEPTANCE OF RESULTS:
- Acceptance criteria met for positive control: yes
- Acceptance criteria met for variability between replicate measurements: yes

Any other information on results incl. tables

Table 1: Depletion of the Cysteine Peptide

Cysteine Peptide
Sample	Peak Area at 220 nm	Peptide Conc. [mM]	Peptide Depletion [%]	Mean Peptide Depletion [%]	SD of Peptide Depletion [%]	CV of Peptide Depletion [%]
Positive Control	809.6354	0.1341	74.93	75.35	0.40	0.53
	794.7175	0.1317	75.39
	783.8397	0.1299	75.72
Test Item	3200.8433	0.5195	0.87	1.34	0.41	30.95
	3175.2896	0.5154	1.66
	3181.4165	0.5164	1.47

  

Table 2: Depletion of the Lysine Peptide

Lysine Peptide
Sample	Peak Area at 220 nm	Peptide Conc. [mM]	Peptide Depletion [%]	Mean Peptide Depletion [%]	SD of Peptide Depletion [%]	CV of Peptide Depletion [%]
Positive Control	1768.9691	0.2117	57.97	56.98	1.07	1.87
	1804.7944	0.2160	57.12
	1858.1759	0.2224	55.85
Test Item	4166.7764	0.4987	0.99	1.29	0.28	22.00
	4152.8242	0.4971	1.32
	4142.9829	0.4959	1.56

 

Table 8: Categorization of the Test Item

Prediction Model	Prediction Model 1 (Cysteine Peptide and Lysine Peptide / Ratio: 1:10 and 1:50)			Prediction Model 2 (Cysteine Peptide / Test Item Ratio: 1:10)
Test Substance	Mean Peptide Depletion [%]	Reactivity Category	Prediction	Mean Peptide Depletion [%]	Reactivity Category	Prediction
Test Item	1.31	Minimal Reactivity	no sensitiser	1.34	Minimal Reactivity	no sensitizer
Positive Control	66.16	High Reactivity	sensitizer	75.35	Moderate Reactivity	sensitizer

Applicant's summary and conclusion

Interpretation of results:

other: The data generated with this method may not be sufficient to conclude on the absence of skin sensitisation potential of chemicals and should be considered in the context of integrated approach such as IATA.

Conclusions:

In an in chemico direct protein reactivity assay (DPRA) according to OECD Guideline 442C, the test item showed minimal reactivity towards both peptides. The test item can be considered as “non-sensitiser”.

Executive summary:

In the present study the test item was assessed for skin sensitising properties by incubating the samples with the peptides containing either cysteine or lysine for 24 ± 2 h at 25 ± 2.5 °C according to OECD Guideline 442C (DPRA). Subsequently samples were analysed by HPLC. For the 100 mM solution of the test item no turbidity or precipitation was observed when diluted with the cysteine peptide solution. After the 24 h ± 2 h incubation period but prior to the HPLC analysis samples were inspected for precipitation, turbidity or phase separation. Slight precipitation was observed for the samples of the positive control (including the co-elution control). Samples were not centrifuged prior to the HPLC analysis. For the 100 mM solution of the test item no turbidity or precipitation was observed when diluted with the lysine peptide solution. After the 24 h ± 2 h incubation period but prior to the HPLC analysis samples were inspected for precipitation, turbidity or phase separation. Phase separation (small droplets on the bottom of the vial) was observed for the samples of the positive control (excluding the co-elution control). Samples were not centrifuged prior to the HPLC analysis. Since the acceptance criteria for the depletion range of the positive control were fulfilled, the observed precipitations and phase separation were regarded as insignificant. The 100 mM stock solution of the positive control (cinnamic aldehyde) showed high reactivity towards the synthetic peptides. The mean depletion of both peptides was 66.16%. No co-elution of test item with the peptide peaks was observed. Sensitising potential of the test item was predicted from the mean peptide depletion of both analysed peptides (cysteine and lysine) by comparing the peptide concentration of the test item treated samples to the corresponding reference control. The 100 mM stock solution of the test item showed minimal reactivity towards the synthetic peptides. The mean depletion of both peptides was ≤ 6.38% (1.31%). Based on the prediction model 1 (Cystein 1:10 / Lysine 1:50 Prediction Model) the test item can be considered as non-sensitiser.