Fumed Silica reactions

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Exposure Standards

Fumed silica

SUBSTANCE NAME:

Fumed silica

CAS Number:

7631-86-9

Synonyms:

Aquafil; CAB-O-SIL; Fossil flour; Aerosil, CAB-O-GRIP

II; Colloidal silica

Exposure Standard:

TWA: - ppm 2 mg/m3 (respirable dust)

STEL: - ppm - mg/m3

E/S first adopted in 1990

No standard should be applied without reference to the

Guidance Note on the Interpretation of Exposure

Standards for Atmospheric Contaminants in the

Occupational Environment [NOHSC:3008(1995)], and to

the related documentation.

Documentation notice: National Occupational Health and

Safety Commission documentation available for these

values.

Note:

(1) Fumed silica should not be confused with silica

fume. Fumed silica is produced synthetically by a

vapour phase hydrolysis of silicon tetrachloride.

Silica fume is the byproduct of a high-temperature

process when elemental silicon is produced by reacting

coke and silica sand (crystalline) in an electric arc

furnace.

(2) Introduction to Silica - Amorphous:

Silicon dioxide, SiO2, exists in two varieties,

amorphous and crystalline. In crystalline forms, the

structures are characterised by tetrahedral

configuration of atoms within the crystals, whereas in

the amorphous forms, the SiO4 (silicate) subunits show

no regular lattice pattern in the structures.

Crystalline silicas show discrete reflections in X-ray

diffraction from the internal planes formed by the

orderly pattern of atoms, while in amorphous silica,

X-rays are scattered randomly and no discrete

reflections are seen. All types of amorphous silica

can be converted to crystalline forms when heated to a

sufficiently high temperature.

The fibrogenic potential of crystalline free silica,

according to one theory, can be attributed to its

tetrahedral configuration of atoms. However, this

hypothesis is still a matter of debate. Bye et al ,

using the enzyme LDH as an indicator of cytotoxicity,

showed that the cytotoxicity of a series of

diatomaceous earth products towards macrophages in

vitro was not dependent on the presence of a

crystalline silica component. The researchers

suggested that crystallinity may not be the only

determinant of fibrogenicity.

It is apparent that whether silica particles can cause

biological damage is determined by their surface

characteristics . Iler postulated that the bonding of

bio-organic molecules on silica particles caused

denaturation of proteins and rupture of cell

membranes. Denaturation of proteins could cause

immunological reactions and rupture of membranes could

cause cell death. This bonding can be attributed to

three forces: ionic attraction, hydrogen bonding and

hydrophobic bonding. Freshly cleaned quartz, and

amorphous silica which have been subjected to high

temperatures, have surfaces that have a predominance

of siloxane groups that can give rise to hydrophobic

bonding to organic molecules .

There are several naturally-occurring and synthetic

amorphous silicas, namely diatomaceous earth,

precipitated silica, silica gel, fumed silica and

silica fume (thermally generated). Synthetic amorphous

silica is usually prepared by vapour-phase hydrolysis,

precipitation or other processes which ensure the

absence of crystalline free silica. Three forms of

synthetic amorphous silica have come on the market in

recent years, according to their method of

preparation: silica gel (silica G), precipitated

silica (silica P) and fumed silica (silica F). Fumed

silica is derived from vapour-phase hydrolysis of a

silicon-bearing halide, such as silicon tetrachloride.

1. IDENTITY

CAS Registry Number:

7631-86-9

Synonyms:

Aquafil; CAB-O-SIL; Fossil flour; Aerosil, CAB-O-GRIP

II; Colloidal silica

Molecula Formula:

SiO2

2. CHEMICAL AND PHYSICAL PROPERTIES

The molecular weight of fumed silica is 69.02. Its

density varies around 2g/ml.

Given below are some of the chemical and physical

properties of fumed silica, in comparison with other

synthetic amorphous forms (5) :

Silica P

Silica G

Fumed Silica

Surface area (m2/g)

125-150

275-325

175-225

pH at 5g/15g H20

6.5-7.5

6.5-7.5

3.4-4.2

Particle size (6)(geometric mean, um)

0.38

0.27

0.17

% Particles <5.0um (6)

98

99.8

99.9

% Particles <1.0um (6)

85

93

99.5

3. MAJOR INDUSTRIAL USES

Fumed silica has a wide range of applications in the

industries of rubber, paper, chemicals and paints. In

the rubber industry, the use of fumed silica enhances

tensile strength, abrasion resistance, stiffness and

gives better colour. In the paper industry, the

qualities of increased opacity and brightness allow

better printability and improved smoothness. In its

application in paints, varnishes and protective

coatings, it provides higher binding power, efficient

extension of prime colours, improved thixotropy and

protection from corrosion.

4. ANIMAL STUDIES

Jahr (7) reviewed the toxicity of amorphous silica and

concluded that amorphous silica caused some tissue

reaction but there was no progression to collagen

formation.

Schepers et al (8) exposed rats to fumed silica at an

airborne concentration of 50mg/m3. The majority of

rats died from pulmonary obstruction and emphysema

after three to five months. Upon cessation of further

exposure, the surviving animals recovered quickly and

the cellular nodules and emphysema were almost

completely resolved.

Groth et al (6) reported an animal inhalation study.

Rats, guinea pigs and monkeys were exposed to fumed

silica, silica gel, or precipitated silica, for 5.5-6

hours/day, 5 days/week, for up to 18 months at 15mg/m3

(total dust) concentration (or 6.9-9.9mg/m3 respirable

dust). Few or no silica-containing macrophages were

found in the lungs and lymph nodes of the guinea pigs

and rats. The most significant finding was that fumed

silica induced early nodular fibrosis in the lungs of

the monkeys. However, the toxic potential of fumed

silica might not have been fully shown in this study,

as an exposure duration of 10-18 months might be

relatively brief for monkeys. The researchers

attributed the fibrogenic action of fumed silica to a

combination of factors: greater surface area, greater

solubility and higher content of aluminium and iron

compounds than the other amorphhous silicas.

5. HUMAN STUDIES

The American Society for Testing and Materials (ASTM)

has reviewed (9) three studies which involved a total

of 353 workers exposed for up to 32 years to fumed

silica at concentrations 1.6-53mg/m3. No pulmonary

dysfunction was observed except in smokers.

Fumed silica and silica fume (thermally generated)

exhibit entirely different toxicities. (Note: the

toxicity of silica fume is still under review by the

Exposure Standards Working Group.) Silica fume has

been shown to have a more significant pneumoconiotic

effect than the synthetic fumed silica (1) .

6. CONCLUSIONM

One animal study indicated that fumed silica is more

toxic than precipitated silica and silica gel. At high

concentrations, it is fibrogenic to animals, but its

fibrogenic potential appears to be far less than that

of crystalline silica.

Fumed silica has only been found in industry in recent

time. The available limited information has not

demonstrated a significant health effect in humans

through occupational exposure.

7. RECOMMENDATION FOR EXPOSURE STANDARD

To protect most workers from pulmonary dysfunction,

the Exposure Standards Working Group recommends a

time-weighted average exposure standard of 2mg/m3

(respirable dust).

REFERENCES

1. American Conference of Government Industrial

Hygienists (ACGIH), Documentation of the Threshold

Limit values and Biological Exposure Indices, 5th

Edition, Ohio, 1986

2. Bye E et al, " In vitro cytotoxicity and

quantitative silica analysis of diatomaceous earth

products " , Brit J Ind Med, 41, 228-234, 1984

3. Baumann H, " Characterization of Silicon Dioxide

surface by successive Determination of the Solution

Rate " , In: Health Effect of Synthetic Silica

Particulates, ASTM STP 732, DD Dunnom Ed., American

Society for Testing and Materials, pp.30-47, 1981

4. Iler RK, " The Surface Chemistry of Amorphous

Synthetic Silica - Interaction with Organic Molecules

in an Aqueous Medium " , In: Health Effects of Synthetic

Silica Particulates, ASTM STP 732, DD Dunnora Ed.,

American Society for Testing and Materials, pp.3-29,

1981

5. Stockinger HE, The Halogens and Nonmetals Boron and

Silicon, In: Patty's Industrial Hygiene and

Toxicology, edited by Clayton GD & Clayton FE, 3rd

rev. ed, Vol 2B, pp 3011-3014, 1981

6. Groth DH et al, " Chronic effects of inhaled

amorphous silicas in animals " , In: Health Effects of

Synthetic Silica Particulates, ASTM STP 732, DD Dunnom

Ed., American Society for Testing and Materials,

pp.118-143, 1981

7. Jahr J, " Possible Health Hazards from Different

Types of Amorphous Silicas " , In: Health Effects of

Synthetic Silica Particulates, ASTM STP 732, DD Dunnom

Ed., American Society for Testing and Materials,

pp.199-213, 1981

8. Schepers GWH et al, " The biological action of

Degussa Submicron amorphous silica dust (Dow Corning

Silica) " , Am Med Assoc Archives of Ind Health, 16,

125-146, 1957

9. American Society for Testing and Materials, Health

Requirements for Occupational Exposure to Synthetic

Amorphous Silica, ASTM Standard E1156-87,

Philadelphia, 1987

Footnotes:

Documentation notice:

Entries carrying a notice for National Occupational

Health and Safety Commission documentation indicate

that these substances have been reviewed in detail by

the Exposure Standards Expert Working Group and that

documentation supporting the adopted national values

is available in the National Commission's

Documentation of the Exposure Standards

[NOHSC:10003(1995)].

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