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Tin(II) fluoride

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Tin(II) fluoride

  Sn2+;   F
Names
IUPAC name
Tin(II) fluoride
Other names
Stannous fluoride
Identifiers
3D model (JSmol)
ECHA InfoCard 100.029.090 Edit this at Wikidata
RTECS number
  • XQ3450000
UNII
UN number 3288
  • InChI=1S/2FH.Sn/h2*1H;/q;;+2/p-2
  • F[Sn]F
Properties
SnF2
Molar mass 156.69 g/mol
Appearance colorless solid
Density 4.57 g/cm3
Melting point 213 °C (415 °F; 486 K)
Boiling point 850 °C (1,560 °F; 1,120 K)
31 g/100 mL (0 °C);
35 g/100 mL (20 °C);
78.5 g.100 mL (106 °C)
Solubility soluble in KOH, KF;
negligible in ethanol, ether, chloroform
Structure
Monoclinic, mS48
C2/c, No. 15
Pharmacology
A01AA04 (WHO)
Hazards
NFPA 704 (fire diamond)
NFPA 704 four-colored diamondHealth 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g. chloroformFlammability 0: Will not burn. E.g. waterInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
2
0
0
Flash point Non-flammable
Safety data sheet (SDS) ICSC 0860
Related compounds
Other anions
Tin(II) chloride,
Tin(II) bromide,
Tin(II) iodide
Other cations
Germanium tetrafluoride,
Tin tetrafluoride,
Lead(II) fluoride
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
☒N verify (what is checkY☒N ?)

Tin(II) fluoride, commonly referred to commercially as stannous fluoride[1][2] (from Latin stannum, 'tin'), is a chemical compound with the formula SnF2. It is a colourless solid used as an ingredient in toothpastes.

Oral health benefits

Stannous fluoride was introduced as an alternative to sodium fluoride for the prevention of cavities (tooth decay). It was introduced for this purpose by Joseph Muhler and William Nebergall. In recognition for their innovation, these two individuals were inducted into the Inventor's Hall of Fame.[1]

The fluoride in stannous fluoride helps to convert the calcium mineral apatite in teeth into fluorapatite, which makes tooth enamel more resistant to bacteria-generated acid attacks.[3] The calcium present in plaque and saliva reacts with fluoride to form calcium fluoride on the tooth surface; over time, this calcium fluoride dissolves to allow calcium and fluoride ions to interact with the tooth and form fluoride-containing apatite within the tooth structure.[4] This chemical reaction inhibits demineralisation and can promote remineralisation of tooth decay. The resulting fluoride-containing apatite is more insoluble, and more resistant to acid and tooth decay.[4]

In addition to fluoride, the stannous ion has benefits for oral health when incorporated in a toothpaste. At similar fluoride concentrations, toothpastes containing stannous fluoride have been shown to be more effective than toothpastes containing sodium fluoride for reducing the incidence of dental caries and dental erosion,[5][6][7][8][9] as well as reducing gingivitis.[10][11][12][13][14] Some stannous fluoride-containing toothpastes also contain ingredients that allow for better stain removal.[15][16] Stabilised stannous fluoride formulations allow for greater bioavailability of the stannous and fluoride ion, increasing their oral health benefits.[17][18] A systematic review revealed stabilised stannous fluoride-containing toothpastes had a positive effect on the reduction of plaque, gingivitis and staining, with a significant reduction in calculus and halitosis (bad breath) compared to other toothpastes.[16] A specific formulation of stabilised stannous fluoride toothpastes has shown superior protection against dental erosion and dentine hypersensitivity compared to other fluoride-containing and fluoride-free toothpastes.[19]

Stannous fluoride was once used under the trade name Fluoristan in the original formulation of the toothpaste brand Crest, though it was later replaced with sodium monofluorophosphate under the trade name Fluoristat. Stabilised stannous fluoride is now the active ingredient in Crest/Oral B Pro-Health brand toothpaste. Although concerns have been previously raised that stannous fluoride may cause tooth staining, this can be avoided by proper brushing and by using a stabilised stannous fluoride toothpaste.[15][16] Any stannous fluoride staining that occurs due to improper brushing is not permanent, and Crest/Oral B Pro-Health states that its particular formulation is resistant to staining.

Production

SnF2 can be prepared by evaporating a solution of SnO in 40% HF.[20]

SnO + 2 HF → SnF2 + H2O

Aqueous solutions

Readily soluble in water, SnF2 is hydrolysed. At low concentration, it forms species such as SnOH+, Sn(OH)2 and Sn(OH)3. At higher concentrations, predominantly polynuclear species are formed, including Sn2(OH)22+ and Sn3(OH)42+.[21] Aqueous solutions readily oxidise to form insoluble precipitates of SnIV, which are ineffective as a dental prophylactic.[22] Studies of the oxidation using Mössbauer spectroscopy on frozen samples suggests that O2 is the oxidizing species.[23]

Lewis acidity

SnF2 acts as a Lewis acid. For example, it forms a 1:1 complex (CH3)3NSnF2 and 2:1 complex [(CH3)3N]2SnF2 with trimethylamine,[24] and a 1:1 complex with dimethylsulfoxide, (CH3)2SO·SnF2.[25]
In solutions containing the fluoride ion, F, it forms the fluoride complexes SnF3, Sn2F5, and SnF2(OH2).[26] Crystallization from an aqueous solution containing NaF produces compounds containing polynuclear anions, e.g. NaSn2F5 or Na4Sn3F10 depending on the reaction conditions, rather than NaSnF3.[20] The compound NaSnF3, containing the pyramidal SnF3 anion, can be produced from a pyridine–water solution.[27] Other compounds containing the pyramidal SnF3 anion are known, such as Ca(SnF3)2.[28]

Reducing properties

SnF2 is a reducing agent, with a standard reduction potential of Eo (SnIV/ SnII) = +0.15 V.[29] Solutions in HF are readily oxidised by a range of oxidizing agents (O2, SO2 or F2) to form the mixed-valence compound Sn3F8 (containing SnII and SnIV and no Sn–Sn bonds).[20]

Structure

The monoclinic form contains tetramers, Sn4F8, where there are two distinct coordination environments for the Sn atoms. In each case, there are three nearest neighbours, with Sn at the apex of a trigonal pyramid, and the lone pair of electrons sterically active.[30] Other forms reported have the GeF2 and paratellurite structures.[30]

Molecular SnF2

In the vapour phase, SnF2 forms monomers, dimers, and trimers.[26] Monomeric SnF2 is a non-linear molecule with an Sn−F bond length of 206 pm.[26] Complexes of SnF2, sometimes called difluorostannylene, with an alkyne and aromatic compounds deposited in an argon matrix at 12 K have been reported.[31][32]

Safety

Stannous fluoride can cause redness and irritation if it is inhaled or comes into contact with the eyes. If ingested, it can cause abdominal pains and shock.[33] Rare but serious allergic reactions are possible; symptoms include itching, swelling, and difficulty breathing. Certain formulations of stannous fluoride in dental products may cause mild tooth discoloration; this is not permanent and can be removed by brushing, or can be prevented by using a stabilised stannous fluoride toothpaste.[15][16][34]

References

  1. ^ a b "National Inventors Hall of Fame Announces 2019 Inductees at CES". National Inventors Hall of Fame. Retrieved 6 February 2019.
  2. ^ "Latin Names Variable Charge Metals". Nobel.SCAS.BCIT.ca/. British Columbia Institute of Technology Chemistry Department. Retrieved 16 June 2013.
  3. ^ Groeneveld, A.; Purdell-Lewis, D. J.; Arends, J. (1976). "Remineralization of artificial caries lesions by stannous fluoride". Caries Research. 10 (3): 189–200. doi:10.1159/000260201. ISSN 0008-6568. PMID 1063601.
  4. ^ a b Lussi, Adrian; Hellwig, Elmar; Klimek, Joachim (2012). "Fluorides - mode of action and recommendations for use". Schweizer Monatsschrift für Zahnmedizin = Revue Mensuelle Suisse d'Odonto-Stomatologie = Rivista Mensile Svizzera di Odontologia e Stomatologia. 122 (11): 1030–1042. ISSN 0256-2855. PMID 23192605.
  5. ^ West, N. X.; He, T.; Macdonald, E. L.; Seong, J.; Hellin, N.; Barker, M. L.; Eversole, S. L. (March 2017). "Erosion protection benefits of stabilized SnF2 dentifrice versus an arginine–sodium monofluorophosphate dentifrice: results from in vitro and in situ clinical studies". Clinical Oral Investigations. 21 (2): 533–540. doi:10.1007/s00784-016-1905-1. ISSN 1432-6981. PMC 5318474. PMID 27477786.
  6. ^ Ganss, C.; Lussi, A.; Grunau, O.; Klimek, J.; Schlueter, N. (2011). "Conventional and Anti-Erosion Fluoride Toothpastes: Effect on Enamel Erosion and Erosion-Abrasion". Caries Research. 45 (6): 581–589. doi:10.1159/000334318. ISSN 0008-6568. PMID 22156703. S2CID 45156274.
  7. ^ West, Nicola X.; He, Tao; Hellin, Nikki; Claydon, Nicholas; Seong, Joon; Macdonald, Emma; Farrell, Svetlana; Eusebio, Rachelle; Wilberg, Aneta (August 2019). "Randomized in situ clinical trial evaluating erosion protection efficacy of a 0.454% stannous fluoride dentifrice". International Journal of Dental Hygiene. 17 (3): 261–267. doi:10.1111/idh.12379. ISSN 1601-5029. PMC 6850309. PMID 30556372.
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  15. ^ a b c He, Tao; Baker, Robert; Bartizek, Robert D.; Biesbrock, Aaron R.; Chaves, Eros; Terézhalmy, Geza (2007). "Extrinsic stain removal efficacy of a stannous fluoride dentifrice with sodium hexametaphosphate". The Journal of Clinical Dentistry. 18 (1): 7–11. ISSN 0895-8831. PMID 17410949.
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  19. ^ West, Nicola X.; He, Tao; Zou, Yuanshu; DiGennaro, Joe; Biesbrock, Aaron; Davies, Maria (February 2021). "Bioavailable gluconate chelated stannous fluoride toothpaste meta-analyses: Effects on dentine hypersensitivity and enamel erosion". Journal of Dentistry. 105: 103566. doi:10.1016/j.jdent.2020.103566. ISSN 1879-176X. PMID 33383100. S2CID 229940161.
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