Registration Dossier

Data platform availability banner - registered substances factsheets

Please be aware that this old REACH registration data factsheet is no longer maintained; it remains frozen as of 19th May 2023.

The new ECHA CHEM database has been released by ECHA, and it now contains all REACH registration data. There are more details on the transition of ECHA's published data to ECHA CHEM here.

Diss Factsheets

Ecotoxicological information

Short-term toxicity to aquatic invertebrates

Currently viewing:

Administrative data

Link to relevant study record(s)

Description of key information

NOEC 78 mg/l for D.magna was determined..

Key value for chemical safety assessment

Fresh water invertebrates

Fresh water invertebrates
Effect concentration:
78 mg/L

Additional information

Read-across concept (environment) for tin bis(tetrafluoroborate):

Tin bis(tetrafluoroborate) is an inorganic substance which will dissociate into tin and tetrafluoroborate ions upon dissolution in the environment (water solubility >50 % w/w).

 

In the environment, tin is likely to partition to soils and sediments. In water, inorganic tin may exist as either divalent (Sn2+) or tetravalent (Sn4+) cations under environmental conditions. Whereas tin(II) dominates in reduced (oxygen-poor) water and will readily precipitate as tin(II) sulfide or as tin(II) hydroxide in alkaline water, tin(IV) readily hydrolyses and can precipitate as tin(IV) hydroxide. In general, tin(IV) would be expected to be the only stable ionic species in the weathering cycle. Tin(II) can be hydrolysed into SnOH+, Sn(OH)2, and Sn(OH)3at low concentrations, and this behaviour can be described by the following equation:

 

SnX2+ H2O <--> "SnXOH"(s) + HX

 

This Sn2+specific behaviour may be a hindrance when conducting tests at low or very low tin concentrations.Since the Sn2(OH)22+and Sn(OH)42+polynuclear species predominate at higher concentrations, highly concentrated and acidified Sn2+solutions are stable and only tend to precipitate at a very low rate.

 

On release to estuaries, inorganic tin is principally converted to the insoluble hydroxide and is rapidly scavenged by particles, which are the largest sinkfor the metal. Subsequent release of inorganic tin from benthic sediments is unlikely, except at highly anoxic sites. Since the mobility of Sn is highly pH dependent, Sn2+is only present in acid and reducing environments. Weathering of most natural and anthropogenic Sn carriers is intensified under acid, reducing conditions, although SnS2is insoluble under reducing conditions. In stream sediment, most detrital Sn is held in resistant oxide phases, such as cassiterite, which release Sn very slowly during weathering. Any Sn2+ released oxidises rapidly and is subsequently bound to secondary oxides of Fe or Al as Sn(OH)4or SnO(OH)3-. Tin forms soluble and insoluble complexes with organic substances. Tin is generally regarded as being relatively immobile in the environment. Ambient levels of tin in the environment are generally quite low. Tin occurs in trace amounts in natural waters, i.e. average concentrations in stream water are assumed to be less than 0.01μg/L (summarised in WHO, 2005 and athttp://www.gtk.fi/publ/foregsatlas, accessed on 12.03.2013).

 

The environmental behaviour of the tetrafluoroborate anion is expected to be different, and in a conservative approach it is assumed that the tetrafluoroborate anion remains stable and mobile under environmental conditions.

 

Upon release to the environment and dissolution in aqueous media, tin bis(tetrafluoroborate) will dissociate and only be present in its dissociated form, i.e. as tin cation and tetrafluoroborate anion, andtoxicity (if any) will be driven by tin and the tetrafluoroborate anion. Therefore,data are read-across for the tin cation and for the tetrafluoroborate anionto assess theecotoxicity of tin bis(tetrafluoroborate).Read-across to other soluble tetrafluoroborates, i.e. potassium tetrafluoroborate (CAS# 14075-53-7) and sodium tetrafluoroborate (CAS# 13755-29-8), and soluble tin substances, including tin bis(methanesulfonate) (CAS# 53408-94-9) and tin dichloride (CAS# 7772-99-8) is fully justified. The lowest effective concentrations of short- and long-term toxicity available for algae, daphnia and fish, respectively, are summarized in the Table below.

 

Short-term aquatic toxicity:

Substance specific guideline data of tin bis(tetrafluoroborate) are available for the acute toxicity to invertebrates (D. magna) and fish (Oncorhynchus mykiss) (Palmieri and Buccafusco, 1983) and EC50/LC50s of 87 mg/L and 78 mg/L, respectively, are well above classification criteria for acute aquatic hazard according to CLP-Regulation (EC) No 1272/2008.

 

Tin:

Wong et al (1982) tested the toxicity of SnCl2to different algal species (Anabaena flosaquae, Ankistrodesmus falcatus, and Scenedesmusquadricauda), and EC50 values when recalculated for tin bis(tetrafluoroborate) indicate a similar lack of acute toxicity to algae; the lowest EC50 for 8-d growth ofA. falcatusis 12 mg/L Sn2+(corresponding to ≥ 30 mg/LSn(BF4)2).

 

Tetrafluoroborate:

A guideline study is available for toxicity of potassium tetrafluoroborate in alga (Pseudokirchnerella subcapitata); the 72-h EC50 for growth rate inhibition is >100 mg/L (corresponding to > 116 mg/LSn(BF4)2).

A guideline study for short-term toxicity is available for aquatic invertebrates; the 48-h EC50 forDaphnia magnais >100 mg/L (corresponding to > 116 mg/LSn(BF4)2).

A guideline study for short-term toxicity is available for freshwater fish; the 96-h LC50 amounts to 760 mg/L for golden orfe (Leuciscus idus) (corresponding to 882 mg/LSn(BF4)2).

 

Table: Aquatic toxicity of tin and tetrafluoroborate substances

 

Tested substance

Effective concentration

(mg/L)

Short-term aquatic toxicity

 

 

Algae - EC50

tin dichloride: SnCl2

potassium tetrafluoroborate: KBF4

> 30*

> 116**

Daphnia – 48-h EC50

tin bis(tetrafluoroborate): Sn(BF4)2

potassium tetrafluoroborate: KBF4

87

> 116**

Fish – 96-h LC50

tin bis(tetrafluoroborate): Sn(BF4)2

potassium tetrafluoroborate: KBF4

78

882**

Long-term aquatic toxicity

 

 

Algae – NOEC

tin dichloride: SnCl2

potassium tetrafluoroborate: KBF4

> 25*

116**

Daphnia - NOEC

tin(II) bis(methanesulfonate): Sn(CH3SO3)2

sodium tetrafluoroborate: NaBF4

11.8*

250**

Fish - NOEC

tin dichloride: SnCl2

19*

Toxicity to microorganisms

 

 

Respiration inhibition – EC10

tin(II) bis(methanesulfonate): Sn(CH3SO3)2

99*

Respiration inhibition – EC50

Pseudomonas putida

tin(II) bis(methanesulfonate): Sn(CH3SO3)2

potassium tetrafluoroborate: KBF4

283*

638**

*Effective concentrations were recalculated for tin bis(tetrafluoroborate) based on an average tin content of 40.6%.

**Effective concentrations were recalculated for tin bis(tetrafluoroborate) based on an average tetrafluoroborate content of 59.4%.

 

Discussion

Substance-specific data indicate a lack of toxicity of tin bis(tetrafluoroborate) to daphnia and fish below acute classification criteria of CLP-Regulation (EC) No 1272/2008 (Table 4.1.0 (a)). Based on read-across of acute algae toxicity data available for tin and tetrafluoroborate, tin bis(tetrafluoroborate) also does not meet the hazard criteria for acute (short-term) aquatic hazard. The lowest available NOEC, i.e. the NOEC of 25 mg/L tin bis(tetrafluoroborate) for growth inhibition of algae is taken forward for the chemical safety assessment.

 

Substance-specific long-term toxicity data are not available for tin bis(tetrafluoroborate). Based on read-across of long-term data available for the toxicity of tin to algae, daphnia and fish, the lowest 21-d NOEC available for toxicity to reproduction ofD. magnarecalculated fortin bis(tetrafluoroborate) amounts to 11.8 mg/L, and this value is taken forward for the chemical safety assessment.

 

Long-term data available to assess the toxicity of tetrafluoroborate to algae and daphnia also indicate a lack of toxicity potential below classification criteria of CLP-Regulation (EC) No 1272/2008 (Table 4.1.0 (b)(i)) for non-rapidly degradable substances. Based on acute toxicity data available for all three trophic levels and the fact that fish are the least sensitive species, it is assumed that effective concentrations for the toxicity of tetrafluoroborate to fish are not below classification criteria for long-term aquatic hazard. Further, according to long-term classification criteria of CLP-Regulation (EC) No 1272/2008, Table 4.1.0 (b)(iii) for substances for which adequate chronic toxicity data are not available, the 96-hLC50 available for toxicity of tetrafluoroborate to fish or any other EC/LC50 available for algae and daphnia would not result in a classification of long-term hazard.

 

Based on read-across of chronic toxicity data available for tin and tetrafluoroborate, tin bis(tetrafluoroborate) also does not meet the hazard criteria for long-term aquatic hazard.

 

According to classification criteria of CLP-Regulation (EC) No 1272/2008 (Table 4.1.0), tin bis(tetrafluoroborate) does not meet the criteria for aquatic hazard and does not require classification and labelling.