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REACH

Cyanuric acid

EC number: 203-618-0 | CAS number: 108-80-5

Life Cycle description
Uses advised against

Environmental fate & pathways

Biodegradation in soil

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Administrative data

Link to relevant study record(s)

Reference 1

Endpoint:: biodegradation in soil: simulation testing
Type of information:: experimental study
Adequacy of study:: key study
Reliability:: 2 (reliable with restrictions)
Rationale for reliability incl. deficiencies:: study well documented, meets generally accepted scientific principles, acceptable for assessment
Principles of method if other than guideline:: The biodegradation of cyanuric acid was studied in a variety of soils and muds
GLP compliance:: no
Test type:: laboratory
Radiolabelling:: yes
Oxygen conditions:: anaerobic
Soil classification:: not specified
Soil no.:: #1
Soil type:: other: Garden
Soil no.:: #2
Soil type:: other: Chemical plant area
Soil no.:: #3
Soil type:: other: Farm
Soil no.:: #4
Soil type:: other: Barnyard (a): air-dried in laboratory for > 6 months. 20 g of H2O was added per 100 g of air dried soil
Soil no.:: #5
Soil type:: other: Barnyard (b): air-dried in laboratory for > 6 months. 20 g of H2O was added per 100 g of air dried soil, experiment started one month after moistening
Soil no.:: #6
Soil type:: other: Barnyard (c): air-dried in laboratory for > 6 months. 90 g of H2O was added per 100 g of air dried soil
Details on soil characteristics:: Sampling sites:
Garden soil: Santa Clara, California, USA
Chemical plant area: S. Charleston, W. Va. USA
Farm: Princeton, N. J. USA
Barnyard: New Brunswick, N. J. USA
Soil No.:: #1
Duration:: 23 d
Soil No.:: #2
Duration:: 23 d
Soil No.:: #3
Duration:: 23 d
Soil No.:: #4
Duration:: 23 d
Soil No.:: #5
Duration:: 23 d
Soil No.:: #6
Duration:: 15 d
Parameter followed for biodegradation estimation:: CO2 evolution
Soil No.:: #1
% Degr.:: 91
Parameter:: CO2 evolution
Sampling time:: 23 d
Soil No.:: #2
% Degr.:: 106
Parameter:: CO2 evolution
Sampling time:: 23 d
Soil No.:: #3
% Degr.:: 103
Parameter:: CO2 evolution
Sampling time:: 23 d
Soil No.:: #4
% Degr.:: 2
Parameter:: CO2 evolution
Sampling time:: 23 d
Soil No.:: #5
% Degr.:: 10
Parameter:: CO2 evolution
Sampling time:: 23 d
Soil No.:: #6
% Degr.:: 52
Parameter:: CO2 evolution
Sampling time:: 15 d
Transformation products:: not specified
Conclusions:: Cyanuric acid biodegrades readily in anaerobic soils

Reference 2

Endpoint:: biodegradation in soil: simulation testing
Type of information:: experimental study
Adequacy of study:: supporting study
Reliability:: 2 (reliable with restrictions)
Rationale for reliability incl. deficiencies:: study well documented, meets generally accepted scientific principles, acceptable for assessment
Principles of method if other than guideline:: The relative degradation rate of cyanuric acid was studied in Greenfield sandy loam soil
GLP compliance:: no
Test type:: laboratory
Radiolabelling:: yes
Oxygen conditions:: aerobic/anaerobic
Soil classification:: not specified
Soil no.:: #1
Soil type:: sandy loam
% Clay:: 6
% Silt:: 29
% Sand:: 65
% Org. C:: 1.1
pH:: 7.1
Details on soil characteristics:: SOIL COLLECTION AND STORAGE
- Soil preparation: The soil was collected from the field, air dried passed through a 2mm sieve and 500 g portions placed in 1-liter Erlenmyer flasks.
Soil No.:: #1
Duration:: 375 d
Parameter followed for biodegradation estimation:: CO2 evolution
Details on experimental conditions:: Soil incubation:
The organic amendment was lima bean straw which contained 1.1% nitrogen and was applied at the rate of 0.5% on a dry weight basis. For aerobic incubation the soil was adjusted to 60% water-holding capcacity and for the saturated soil treatment 20% water in excess of capacity was added. 2.5 ppm of 14-C cyanuric acid was added to the soil in solution to give a concentration of 2.5 ppm on a dry soil basis. Treatments were made in duplicate.

CO2 free air was continuously passed over the soil surface in the flasks and the CO2 evolved was collected in 25 ml of 3N KOH.

Fungal incubation:
Stachybotrys chartarum and Hendersonula toruloidea were cultured. Fungal pads were harvested by filtration, washing and lyophilization. Humic-type polymers present in the culture solution of these fungi were concentrated at 65°C, dialyzed against frequent changes of distilled water and lyophilized.
Transformation products:: not specified
Conclusions:: After 16 days 87% of the labeled cyanuric acid had evolved as 14CO2 and after 32 days the percentage had increased to 96% indicating that after ring cleavage the cyanuric acid C is not used for cell synthesis by the soil organisms. Evolution of 14CO2 was retarded under saturated soil conditions. Losses were 83% for cyanuric acid in 66 days. Pure culture studies with two soil fungi, Stachybotrys chartarum and Hendersonula toruloidea could degrade cyanuric acid to CO2.

Reference 3

Endpoint:: biodegradation in soil: simulation testing
Data waiving:: other justification
Justification for data waiving:: other:
Justification for type of information:: JUSTIFICATION FOR DATA WAIVING
Cyanuric acid biodegrades readily in anaerobic soils [1]. CYA naturally occurs in soils at concentrations of 0.9 to 6.5 ppm[2]. The presence and identification of the levels of CYA found in the study predate the large scale commercial manufacture and use of products which breakdown to CYA thus providing evidence that the substance occurs due to other sources. CYA is also present in soil as a result of plant protection products such as the S-triazines, atrazine and simazine which have been commercially used for over 40 years. [3] The s-triazine herbicides undergo enzyme catalysed degradation yielding CYA as an intermediate, which is then hydrolytically processed to ammonia and carbon dioxide. Urea and other urea based compounds used as fertilizers can also form CYA as an intermediate. References: 1.Saldick, J. (1974) Biodegradation of cyanuric acid. Applied Microbiology 28 (6) 1004 – 1008. 2.Wise L E and Walters E H (1917) Isolation of Cyanuric Acid from Soil. Journal of Agricultural Research. 10(2) 85 - 91. 3.Müllar PW and Payot PH (1966) Fate of 14C-labelled Triazine herbicides in plants Isotopes and Weed Research Proceedings of the IACA Symposium, Vienna, Austria, 1966 p61-70, 4. Cook AM and Hutter R (1981) sTriazines as Nitrogen Sources fro Bacteria J. Agr. Food. Chem 29:(6), Eaton RW and Karns JS (1991) Cloning and Analysis of s-Triazine catabolic genes from Pseudomonas spp. strain NRRLB-12227, Journal of Bacteriology p.1215-1222, Vol. 173, No. 3

Description of key information

CYA biodegrades readily in soils.

Key value for chemical safety assessment

Additional information

In a series of studies performed in different anaerobic soils (Saldick J 1974) it was observed that CYA biodegrades readily in anaerobic soils. Over a 23 day period degradation was highest when there is a large water to solid ratio and a potentially large anaerobic microorganism population, for example 100% degradation in farm soil in 23 days.

In a further study (Wolf & Martin 1975) the relative degradation rate of cyanuric acid was studied in Greenfield sandy loam soil. After 16 days 87% of the labelled cyanuric acid had evolved as 14CO₂ and after 32 days the percentage had increased to 96% indicating that after ring cleavage the cyanuric acid C is not used for cell synthesis by the soil organisms. Evolution of 14CO₂ was retarded under saturated soil conditions. Losses were 83% for cyanuric acid in 66 days. Pure culture studies with two soil fungi, Stachybotrys chartarum and Hendersonula toruloidea could degrade cyanuric acid to CO₂.

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Reproduction or further distribution of this information may be subject to copyright protection. Use of the information without obtaining the permission from the owner(s) of the respective information might violate the rights of the owner.

Medium	Days at room temp	¹⁴C added evolved as CO₂ (%)
Soils:
Garden	23	91
Chemical plant area	23	106
Farm	23	103
Barnyard^a	23	2
Barnyard^b	23	10, 13
Barnyard^c	15	52

Treatment	Time after treatment (days)
Treatment	16	32	66	192	264	375
Aerobic soil	87	96	98	99	-	-
Aerobic soil plus bean straw	96	98	99	99	-	-
Saturated soil	N.S	57	83	97	98	99
Saturated soil plus bean straw	N.S	76	87	93	93	94

Growth and CO₂evolution
H. toruloidea	S. chartarum
Dry weight of pads
mg per 100 ml of medium
687	319
CO₂evolution
mg C as CO₂per100 ml of medium
950	599

Percent activity recovered as
H. toruloidea
¹⁴CO₂	Cell material	Humic type polymer
15.1	6.3	53.8
S. chartarum
99.4	0.0	3.6

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Cyanuric acid

Biodegradation in soil

Administrative data

Link to relevant study record(s)

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Reference 1

Reference 2

Reference 3

Description of key information

Key value for chemical safety assessment

Additional information

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