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Description  |
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The invention relates to the modification of the surface properties of
porous or divided bodies, by grafting organic groups of atoms thereto
through a silcon atom, wherein the organic groups have properties of a
hydrophilic character, primarily for imparting to the bodies particular
chromatographic properties.
The extremely wide range of uses of the surface properties of many natural
or synthetic porous or divided bodies is known. Such bodies include, for
example, clays, diatomaceous earth, zeolites, active carbon and various
oxides. The colloidal state of many of these bodies is favorable to the
manifestation of such surface properties; all these bodies owe their
properties to the development of their surface, which is related to the
porosity characteristics in the case of porous bodies, or to the
elementary dimensions of small particles when the bodies are in a highly
divided form, including colloidal form.
Among these various bodies, industry is tending more and more to turn to
synthetic compounds, to which it is possible to impart well defined and
reproduceable properties. Among such compounds, the choice falls on a
fairly restricted class comprising some oxides and hydroxides and mixtures
thereof, the most important of them being those of silicon, aluminium and
magnesium.
Among the uses of the surface properties of various bodies, chromatography
in its various aspects is one of the most interesting, not because of the
quantities of substances treated but because of the high degree of
selectivity which can be achieved in separation operations and, in return,
because of the wide variety of surface properties of the various compounds
which such separation operations can bring into play. A long time ago, for
example, a practical device for chromatographic separation was perfected,
which comprises passing a fluid containing the substance or substances to
be separated, through tubes whose length is great in relation to their
diameter, with the tubes being filled with various porous bodies. Among
these porous bodies, siliceous bodies are frequently used because of the
various surface and porosity characteristics which can be imparted
thereto.
However, when used for carrying out certain separation operations by means
of chromatographic methods, siliceous porous bodies do not give the
expected results. The reasons for this phenomenon are probably due to the
high degree of reactivity of their residual functions and the particular
adsorbent properties of the siliceous porous bodies.
In order to overcome these disadvantages, it has been proposed to modify
the surface properties of siliceous bodies by impregnation with various
organic chemical compounds, called stationary phases, in a monomolecular
or plurimolecular layer. This method suffers from many disadvantages, due
to the low degree of affinity of the stationary phases for silica, which
means that the fillings for chromatographic columns lack stability, due,
for example, to the volatility of the stationary phases or their
solubility in the eluants used.
Moreover, it is well known that it is generally possible to react the
hydroxyls present on the surface of various defined solid chemical
compounds, or even on the surface of any bodies, and in particular the
hydroxyls which are present on the surface of siliceous bodies, with many
chemical compounds of carbon and silicon, which are capable of removing
the hydrogen atoms from the hydroxyls and becoming fixed to the surface of
the bodies, by means of bonds which are formed between the oxygen atoms of
the hydroxyls and the silicon or carbon atoms of the chemical compounds.
Such groups of atoms and radicals can be complex.
It has been recommended that this mode of operation be used to fix various
groups of atoms acting as stationary phases, in particular on the porous
bodies obtained from silica gels or from glasses, which can be provided
with micro-porosity by means of particular treatments, thus improving the
properties of such bodies for chromatographic uses. In particular, such
grafting of groups of atoms by means of silicon atoms of various organic
silanes is more attractive as being substantially irreversible, due to
good resistance of the products to heat and hydrolysis.
However, the separation of particularly fragile molecules, often of
biological origin, such as proteins and enzymes, is frequently poor, even
on siliceous bodies on which groups of atoms have been grafted by means of
the various silanes mentioned above.
It is accordingly an object of the present invention to provide porous or
divided bodies which overcome the foregoing disadvantages, and it is a
more specific object of this invention to provide porous or divided bodies
to which hydrophylic organic groups have been grafted for use in
chromatographic separations.
It has been found in accordance with the present invention that porous or
divided bodies for use in chromatographic separation of polar molecules
and particularly molecules such as those of enzymes and proteins can be
prepared by grafting onto such bodies, through the --O--Si-- bond, organic
groups having an average molecular weight of more than 150 and preferably
within the range of 200 to 4000 and having at least one functional group
which imparts to the organic groups hydrophilic characteristics. Such
functional groups are of themselves well known and included ether, alcohol
(hydroxy) and pyrrolidone functions.
So that grafting of these groups can be effected, it is desirable to start
from a silicon-containing chemical compound comprising, in addition to the
organic groups described above, a silicon atom, and, linked to the silicon
atom, at least one radical or atom capable of reacting with a residual
hydroxyl of the porous or divided bodies, by removing the hydrogen from
said hydroxyl.
For grafting a suitable number of groups, it is desirable that the porous
or divided bodies should have a sufficient density of hydroxyls. In most
cases the density of hydroxyls is higher than 0.5 hydroxyl per 100 of the
surface area, and preferably from 1.5 to 4 per 100 A.sup.2.
Among porous bodies which are capable of being treated in accordance with
this invention mention can be made, as being particularly suitable, of
silica gel bodies in which the development of porosity is effected
thermally, in the presence of foreign atoms such as alkali metals and
certain atoms capable of giving acid functions, or hydrothermally in the
presence of ammonia. Such methods are described in French Pats. Nos.
1,473,240, 1,482,867 and 1,528,785, and also in copending U.S. application
Ser. No. 147,241 filed on May 20, 1971 now abandoned, and U.S. application
Ser. No. 20,850, filed Mar. 18, 1970 now U.S. Pat. No. 3,696,053, and
provide bodies of widely varying porous characteristics and shape, the
distribution of the pore dimensions being within a more or less restricted
range according to the treatments to which the initial gel is subjected.
Silicon-bearing chemical compounds capable of being used for achieving the
desired grafting on porous or divided bodies can have widely varying
formulae, and can be produced by using known methods, such as the addition
of a compound comprising a vinyl or allyl termination and at least one
hydrophilic radical and a simple silane, or by co-polymerisation of a
vinyl monomer containing at least one hydrophilic radical and an
unsaturated silane, that is, an organo silane in which the organic group
contains ethylenic unsaturation.
The grafting of suitable groups on the porous or divided bodies, by using
silicon-containing compounds, must be effected while avoiding other
reactions of hydrolysis of the silicon-containing compounds. Such
reactions can occur with the water simply adsorbed by the porous or
divided bodies; therefore the bodies to be treated should be carefully
dried. The grafting of the organic group onto the bodies is effected by
contacting the porous or divided bodies with the organo silicon compound
which can be in the liquid or vapor phase. If desired, the organo silicon
compound can be dissolvent in an inert solvent for contact with the porous
or divided bodies. After the bodies are contacted with the organo silicon,
the bodies are preferably washed with an inert solvent, dried and then
subjected to a heat extraction step in the presence of one of such
solvents over a period of up to a few hours for the purpose of removing
any fraction of the organo silicon compound which has simply been absorbed
and not chemically bonded or grafted through the oxygen atoms of the
hydroxyl groups.
The porous or divided bodies, modified by the grafting of groups, in
accordance with the present invention, are found to have, in addition to
their hydrophilic properties and their resistance to heat and hydrolysis,
a good degree of resistance to the action of many organic solvents such as
acetone or toluene. Thus, the modified bodies enjoy a group of properties
which permit them to be used in many different chromatographic processes
such as exclusion chromatography, which can be used for separating
biopolymers and water-soluble polymers, separation by division in liquid
or gaseous chromatography and separation by adsorption in liquid or
gaseous chromatography, the liquid media being aqueous or organic.
The following examples show the good results obtained with silica gel
bodies whose surface properties are modified in accordance with the
present invention, because the silica gel is particularly suitable for the
production of highly porous substances, with varying ranges of porosity;
examples are also given by way of comparison, to show the unsatisfactory
degrees of separation achieved by graftings which do not comply with the
characteristics set out hereinbefore. It will be understood that the
examples which illustrate the practice of this invention are provided by
way of illustration, and not by way of limitation.
EXAMPLE 1
This example concerns exclusion chromatography.
The porous bodies subjected to the grafting operation are silica gel
microballs having the following characteristics:
diameter: 100 to 200 .mu.
specific surface area: 130 sq.m/g
pole volume: 0.8 ml/g
mean pore diameter: 225 A
number of hydroxyls: 2 per 100 A.sup.2.
(the last characteristic is determined by calculation from measurement of
the increase in weight, produced by reaction on hexamethyldisilazane of a
specimen of the dried microballs, the grafting effected in this way
involving virtually all the hydroxyls present). 80g of the silica gel
microballs, after preliminary drying at a temperature of 150.degree.C for
a period of 3 hours under a pressure of 0.1 mm mercury, are brought into
contact with a solution of a volume of 400 cm.sup.3 composed of toluene
and 40g of a silane prepared by the addition of dimethylchlorosilane, of a
condensation compound of ethylene oxide having a vinyl termination, of the
formula:
CH.sub.2 = CH.sub.2 --CH.sub.2 (OCH.sub.2 -- CH.sub.2).sub.n OH
in which n has a value of from 8 to 10 (silane A).
The microballs treated in this way are then washed with toluene, dried with
a pump, and then for 1 hour in a drying oven at 110.degree.C.
The amount of carbon contributed by the groups which are grafted in this
way is 5.4% by weight of the treated microballs, which corresponds
approximately to saturation of 80% of the hydroxyls present.
Thermogravimetric analysis of the treated microballs, effected under
nitrogen with a linear programming for a rise in temperature of
200.degree.C/hour, shows a loss in weight by heat decomposition only from
280.degree.C, which shows the heat stability of the grafting.
The treated microballs are used to fill a glass column with a diameter of
2.5 cm and a length of 20 cm, which is eluted at a rate of 200 ml/hour
with a buffer solution having a pH-value of 7.5. The chromatographic
assembly used comprises an injection valve, an ultraviolet detector
operating at a wave-length of 276 millimicrons, provided with a
logarithmic registering device, which permits quantitative evaluation of
the eluted substances, and a cell having a constant volume of 8 ccm, for
measuring the elution volume of the injected constituents.
Into the column is injected a 1% solution in water of the equal-weight
mixture of phthalic acid and blue dextran, which has a molecular weight of
about 2.10.sup.6 and is currently used as a standard for chromatography in
aqueous medium. The difference in the elution volumes of the two compounds
is 32 ccm, which permits evaluation at 0.75 ml/g of the chromatographic
pore volume of the filling in the column, which volume is substantially
the same as that of the initial microballs; this demonstrates the
hydrophilic character of the filling formed by treated microballs.
Once tested in the above manner, the colume is used to treat various
solutions of varied enzymes and proteins, each sort of molecule being in a
0.5% by weight solution in the same buffer as that used to elute the
column; the above mentioned proteins and enzymes are currently used as
chromatography standards.
For each of the chromatograms produced, measurements are taken of the
elution volumes evaluated in multiples of 8 ccm, and the areas of the
peaks which make it possible to calculate the proportion in % of each of
the molecules in question, which are recovered in the elution step, and
the proportions in % of any impurities which may be present.
By way of comparison, the same tests are carried out on the same column,
but the filling of the column comprises the same amount of microballs
which have not been treated.
The results obtained are shown in the following table:
TABLE
______________________________________
Untreated
Treated microballs
microballs
Amount of
eluted
molecules Elution Amount of
Molecules subjected
or eluted volume eluted
to the tests impurities of the molecules
(proteins or enzymes)
in % of peak in in % of the
and approximate
the injected
multiples
injected
molecular weight
amount of 8 ccm amount
______________________________________
cytochrome C
(contains 0.43 % Fe)
>90 8 0
13,000
horse myoglobin
18,000 >90 6.7 0
<5(impurity)
4
bovine hemoglobin
>95 6 0
64,000 <1(impurity)
4
albumin of >95 5 *50
human serum *2(impurity)
8
67,000
.gamma. globulin of
>90 4.4 *10
human serum
160,000
fibrinogen of a
>90 4 *50
bovine serum *5(impurity)
8
330,000
thyroglobulin of
>90 4 *10
a bovine serum
<5(impurity)
8
600,000
______________________________________
*denotes an aproximate value.
This table shows, by comparing the elution volumes obtained for the series
of molecules, that classification follows the increase in molecular
weight, and that the elutions are virtually total when the tests are
carried out on treated microballs, whereas the untreated microballs act as
adsorbants which permit only poor elution or no elution at all.
An aging test over 4 weeks, by elution, at 50 ml/h at from 25 to
30.degree.C, of the column containing the treated microballs, did not
cause a reduction in the results obtained, which shows the stability of
the grafted groups of atoms.
EXAMPLE 2
This example is intended to show by comparison with the results obtained
with the treated microballs of the preceding example, the necessity that
the groups of atoms arising from the silane should be of sufficient
weight.
In the present case, the silane permitting grafting of groups of atoms has
the following formula:
##STR1##
and is plainly of low molecular weight (silane B).
In the same general manner as in the preceding example, the same microballs
are treated by a solution in toluene of the silane B; the grafting effect
is verified by carbon quantitative determination, the amount of carbon
attaining 1.8 % by weight of the treated microballs, which, taking into
account the amounts of carbon present in the two groups of atoms resulting
from the silanes A and B, corresponds to a higher degree of efficiency of
the grafting reaction. The treated microballs are used in the same manner
as in the preceding example, for the chromatography of some of the
molecules used in the preceding example. The following table gives the
results obtained as regards the proportion of such molecules which occur
in the eluted portions.
TABLE
______________________________________
Molecules subjected to
Amount of molecules eluted
the tests in % of the amount injected
______________________________________
myoglobin < 10
albumin < 10
.gamma. globulin < 10
fibrinogen < 10
thyroglobulin
40
______________________________________
-denotes an aproximate value.
This example shows that silane B, although having hydrophilic functions,
like silane A, gives rise to an unfavorable modification of the
chromatographic properties, except as regards thyroglobulin whose eluted
amount remains much lower than in the case of the elution effected in
Example 1 on treated balls.
EXAMPLE 3
This example also concerns exclusion chromatography, by means of microballs
treated by another silane having the following formula:
##STR2##
whose molecular weight is of the order of 550 and which has a hydrophilic
function.
Grafting is effected on silica gel microballs having the following
characteristics:
diameter: 100 to 200 .mu.
specific surface area: 6 sq.m/g
pore volume: 0.8 ml/g
mean pore volume: 5200 A
number of hydroxyls: 1.9 per 100 A.sup.2.
The hydrophilic character of the treated microballs is verified in the same
manner; the column used is a little different from that used in the
preceding examples. By way of comparison, tests are also carried out with
the same amount of untreated filling, in the same column.
The results obtained for some of the molecules used in Example 1 are
indicated in the following table:
TABLE
______________________________________
Untreated
Treated microballs
microballs
Amount of Elution
molecules volume of Amount of
eluted in the peak molecules
% of the in eluted in %
Molecules subjected
amount multiples of the amount
to the tests
injected of 8 ccm injected
______________________________________
cytochrome C > 95 9 0
myoglobin > 95 9 0
albumin > 95 9 < 60
4.5 (impurity)
Thyroglobulin
> 95 8 < 60
4.5 (impurity)
______________________________________
This test shows that the silane C used in this example is suitable for
treating carriers having very high mean pore diameters, and permits
separation of molecules of high molecular weights.
EXAMPLE 4
This example also concerns exclusion chromatography. The silane used has a
molecular weight evalued at 1900, and has the following formula:
##STR3##
It is produced by the addition to dimethylchlorosilane of a polycondensate
of propylene oxide and ethylene oxide, containing approximately 2
molecules of ethylene oxide for one molecule of propylene oxide and end
blocked with acetic acid and allyl alcohol. The microballs treated in a
similar manner to that described in Example 1 have the following
characteristics:
diameter: 100 to 200 .mu.
specific surface area: 280 sq.m/g
pore volume: 0.85 ml/g
mean pore diameter: 108 A
number of hydroxyls: 2.1 per 100 A.sup.2.
The amount of carbon fixed is 6.70% by weight of the treated microballs.
34 g of the microballs are used under the same conditions as those in
Example 1; the chromatographic pore volume, determined in the same manner
as in Example 1, is 0.4 ml/g, this lower value resulting from the greater
bulk of the grafted groups of atoms.
The molecules tested here are bovine hemoglobin and albumin of human serum,
which are totally adsorbed on the untreated microballs; on the microballs
which have been modified by grafting, these two proteins are eluted
quantitatively as from the first injection.
EXAMPLE 5
This example also relates to exclusion chromatography. The silane used has
the following general formula:
##STR4##
in which the ratio m/n is close to 3. This silane is produced by
free-radical co-polymerisation of vinyl triethoxysilane with
N-vinylpyrrolidone; it occurs in the form of a viscous oil whose mean
molecular weight, as evaluated by measurement by means of a vapor-tension
osmometer in benzene at 37.degree.C, is almost 3,500.
Grafting is effected in a general manner similar to that set forth in
Example 1 and on the same microballs, at a rate of 7 g of silane per 50 g
of the microballs.
After washing and drying, there remains on the microballs 0.55 % by weight
of nitrogen and 4.65% of carbon, which shows the reality of the grafting;
the hydrophilic character is shown, as in the preceding examples, by means
of tests with phthalic acid and blue dextran.
Chromatographic tests are effected under conditions substantially identical
to those of Example 1, on various molecules. The results obtained are
given in the following table:
TABLE
______________________________________
Elution volume of
Amount of molecules
Molecule subjected
the main peak in
eluted in % of the
to the tests
multiples of 8 ccm
amount injected
______________________________________
phthalic acid
8.4 100
cytochrome C
7.4 95
myoglobin 7.1 "
hemoglobin 6.6 "
albumin 5.9 "
globulin 5.15 "
fibrinogen 4.8 "
blue dextran
4.8 100
______________________________________
A reduction is noted in the pore volume of the carrier due to the already
high bulk of the silane. It should be noted that all the molecules tested
are eluted totally with the precision close to the measurement, whereas
they were almost totally irreversibly adsorbed on the untreated carrier.
EXAMPLE 6
This example relates to the separation of polyvinyl alcohols by exclusion
chromatography. Here use is made of the silane A described in Example 1,
for treating, in a general manner similar to the preceding examples,
silica microballs having the following characteristics:
diameter: 100/125 .mu.
specific surface area: 60 sq.m/g
pore volume: 0.95 ml/g
mean pore diameter: 480 A
number of hydroxyls: 1.95 per 100 A.sup.2.
at a rate of 15 g per 100 g of microballs.
The substance obtained is used for filtering an analytical column having a
length of 4 mm and a diameter of 0.8 cm, the column being followed by a
differential refractometer detector. In the absence of narrow
characterised fractions of polyvinyl alcohols, two commercial polyvinyl
alcohols are used, bearing the designations RHODOVIOL 4/20 and RHODOVIOL
60/20, containing the same proportion of free acetate. These two polyvinyl
alcohols are injected separately, each injection being of a volume of 0.5
ml and containing 0.5% by weight of alcohol dissolved in water; elution is
effected by demineralised and degasified water at a rate of 60 ml/h.
Comparison of the chromatograms obtained clearly shows that the two
polyvinyl alcohols are of different mean molecular weights, RHODOVIOL
60/20 being the higher; the latter gives a peak located before the
beginning of elution of RHODOVIOL 4/20; the two peaks are devoid of any
trail exceeding the total elution volume of the column.
By comparison, the same tests carried out on untreated microballs do not
show quantitative elution, the peaks obtained being highly asymmetrical
and the trails exceeding the volume of the column.
EXAMPLE 7
This example concerns separation of aromatic compounds by adsorption
chromatography in aqueous medium. Silane A as described in Example 1 is
used here, to treat in a general manner similar to those described
hereinbefore, microballs having the following characteristics:
diameter: 40 to 100 .mu.
specific surface area: 40 sq/m/g
pore volume: 0.85 ml/g
mean pore diameter: 60 A
number of hydroxyls: 1.9 per 100 A.sup.2
at a rate of 16 g of silane per 100 g of microballs.
The length of the column used is 200 cm and its diameter is 1 cm, the
detector being an ultra-violet spectrophotometer, the wavelength being
adjusted for the best sensitivity according to each aromatic compound.
The aromatic compounds tested are benzylamine, aniline, phenol and
pyridine, which are injected separately; elution is effected by a buffer
having a pH-value of 7.5.
By way of comparison, the same tests are carried out on untreated
microballs.
The following table gives the .lambda.-wavelengths used for detecting each
aromatic product, and the division coefficients K. The coefficients K are
determined from the various elution volumes obtained and the interstitial
and pore volumes of the column, in accordance with the relationship
elution V = interstitial V + K pore V.
(The elution volume is defined as the volume of eluent which flows before a
peak appears on the chromatogram; interstitial volume is the volume
comprised between the microballs, and pore volume is that of the microball
pores).
TABLE
______________________________________
K:microballs
detector .lambda.
treated with
K:untreated
compounds in .mu. Silane A microballs
______________________________________
Benzylamine
248 2.35 1.0
Aniline 255 3.08 3.0
Phenol 276 3.38 1.8
Pyridine 280 3.55 1.0
______________________________________
It appears that the division coefficients always increase, which clearly
shows the benefit of the treated microballs, for separating aromatic
compounds. Moreover, it is found that the elution order is different,
which indicates the influence of the grafted groups of atoms. It should be
noted that separation of benzylamine from pyridine is not effected on
untreated microballs.
EXAMPLE 8
This example concerns separation by exclusion chromatography in a
non-aqueous medium, the compounds tested being solutions in acetone
titrating 0.5% by weight of fractions of polyethyleneglycol having mean
molecular weights of 2020, 1220 and 790, on the same treated microballs as
those used in the preceding example. The length of the column used is 1.50
m, while its diameter is 0.8 cm. It is followed by a refractometric
detector. The injected volumes are 0.5 ml, elution being effected by
acetone at a rate of 50 ml/hour. The elution volumes obtained, together
with that given by benzene with a much lower molecular weight, are
measured. The results produced are given in the following table:
TABLE
______________________________________
Elution volumes in
Compound arbitrary units.
______________________________________
polyethyleneglycol 2020
6.1
polyethyleneglycol 1220
6.8
polyethyleneglycol 790
7.5
benzene 8.5
______________________________________
The elution volumes are arranged correctly in the order of decreasing
molecular weights, the test with benzene showing that there is no lag in
elution, and therefore no irreversible adsorption.
As an indication, the same microballs which are untreated totally adsorb
the same compounds dissolved in acetone. Moreover, prolonged use of the
column, over a period of about a month, with the same solvent medium, has
not modified the properties thereof.
EXAMPLE 9
This is an example of separation by chromatography in gaseous phase, of a
mixture of alcohols.
Silane A as described in Example 1 is used in a similar manner, to treat
microballs having the following characteristics:
diameter: 100/200 .mu.
specific surface area: 100 sq.m/g
pore volume: 1 ccm/g
mean pore diameter: 320 A
number of hydroxyls: 2.1 per 100 A.sup.2.
By way of comparison, use is made for the same separation operation, on the
one hand of microballs which have been modified by the addition of a
commercial stationary phase, which is a polyoxyethylene having a molecular
weight of 400, at a rate of 20 g per 100 g of microballs and on the other
hand, of untreated microballs. The length of the column used is 200 cm,
while its internal diameter is 0.3 cm. It is followed by a detector in the
form of a catharometer.
The tests relate to an equal-weight mixture of methanol, ethanol and
isopropanol, the carrier gas being nitrogen.
It is found that the untreated microballs permit elution only from
150.degree.C and do not give symmetrical peaks, that the microballs
treated by the stationary phase give symmetrical peaks at 55.degree. C but
give poor separation of methanol from ethanol, and that microballs treated
by silane A give good separation of the three alcohols as from a
temperature of 50.degree.C, which shows their superiority.
Supplementary tests as to heat stability of the microballs treated by the
stationary phase present a drift as from 105.degree.C, whereas the drift
only appears as from 240.degree.C for microballs treated with silane;
these figures are confirmed by the curves in respect of the weight losses
by heating under nitrogen at a rate of 10.degree.C per minute, of the two
samples.
As will be appreciated by those skilled in the art, a number of organo
silicon compounds can be used in the practice of the invention in addition
to those described. As indicated, the organo silicon should contain at
least one organic group attached directly to the silicon atom which has an
average molecular weight of more than 150 and preferably an average
molecular weight within the range of 200 to 4000 and which has hydrophilic
characteristics. Such characteristics are found in organic groups
containing ether, hydroxy and/or pyrrolidone functional groups.
In addition, the organo silicon compound should also contain from 1 to 3
readily hydrolyzable groups, such as halogen atoms (e.g., chlorine atoms)
or lower alkoxy groups (e.g., methoxy, ethoxy, propoxy) attached to the
silicon atom. Such hydrolyzable groups are reactive with the hydroxyl
groups of the porous or divided bodies to or from the desired
--O--Si--bond between the bodies and the hydrophilic organic group.
As is well known to those skilled in the art, such organo silicon compounds
can be prepared by reaction of a silane of the formula
##STR5##
wherein Z.sub.1 is selected from the group consisting of halogen and
preferably chlorine, or lower alkoxy (e.g., methoxy, ethoxy, propoxy,
etc.). and Z.sub.2 and Z.sub.3 are selected from the group consisting of
halogen or alkoxy as described above, or alkyl containing 1 to 5 carbon
atoms, aryl and preferably phenyl and substituted derivatives thereof with
an organic compound containing terminal ethylenic unsaturation and
containing the desired hydrophilic groups. Preferred organic compounds are
polyoxyalkylene compounds containing terminal ethylinic unsaturation; such
compounds may or may not contain a terminal hydroxy group.
Also contemplated for use in the present invention are the organo silicon
compounds prepared by copolymerization of a silane containing 1 to 3
readily hydrolyzable groups as described above and at least one organic
group containing a polymerizable ethylenic group (e.g. a vinyl group, an
allyl group, etc.) with a monomer containing a hydrophilic group, such as
a pyrrolidone group. The organic group contained in the resulting product
should have an average molecular weight as specified above.
It will be understood that various changes and modifications can be made in
the details of procedure, formulation and use without departing from the
spirit of the invention, especially as embodied in the following claims.
* * * * *
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