Cleaning compositions for solid surfaces – auxiliary compositions – Cleaning compositions or processes of preparing – Specific organic component
Reexamination Certificate
2000-05-26
2003-05-20
Gupta, Yogendra N. (Department: 1751)
Cleaning compositions for solid surfaces, auxiliary compositions
Cleaning compositions or processes of preparing
Specific organic component
C528S010000, C528S014000, C528S022000, C528S026000, C528S027000, C528S028000, C528S029000, C528S041000, C525S475000
Reexamination Certificate
active
06566322
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to silicone-based surfactants, and in particular silicone-based surfactants useful as chelating agents.
BACKGROUND OF THE INVENTION
A wide variety of applications require control of the interfacial properties between immiscible components, such as water-in-oil emulsions or oil-in-water emulsions. Generally, to obtain good performance it is necessary to stabilize the interface between the two immiscible components. One simple example is the use of coupling agents to modify silica surfaces so that silica may be used to reinforce organic polymers, with which it is otherwise incompatible. Another example is the use of surfactants to stabilize oils in water, such as in cleaning and conditioning applications.
Silicones are among the most surface-active materials (“surfactants”) known. They diffuse rapidly to interfaces and readily spread. Spreading of the silicone may be facilitated by the incorporation of polar groups on the silicone backbone. Some of the most effective spreading compounds, particularly at solid/liquid/air surfaces, are the so-called “superwetters” made by manufacturers including Crompton Corp. and Dow Corning. The general structure of these superwetters is (Me
3
SiO)
2
SiMe(CH
2
)
3
(OCH
2
CH
2
)
n
OZ, where Z may be H, CH
3
, CH
3
COO, etc.
Liquid-liquid interfaces are generally stabilized with silicones bearing non-ionic hydrophilic groups. Common examples include derivatives of so-called silicone polyols; that is silicones containing polyether sidechains. U.S. Pat. No. 5,707,613 to Hill teaches that these compounds are particularly useful water/silicone interfaces. Ionic silicone copolymers can also be used to stabilize such interfaces. U.S. Pat. No. 5,124,466 to Azechi et al. (Shin-Etsu) teaches that ammonium-modified silicone surfactants are useful in the stabilization of silicone emulsions in water.
The surface activity of silicones, whether cationic, zwitterionic or non-ionic, cannot be readily changed, although pH modifications may affect the behavior of some types of ammonium compounds. There are advantages in being able to change the surface activity of a surface active material so as to change the properties of systems in accordance with its particular use, for example, to flocculate emulsions on demand. For example, carboxylic acids and polymers derived from them (e.g., CARBOPOL™ (available from BF Goodrich)) change their ability to swell water and to stabilize interfaces upon pH changes: bases convert neutral carboxylic acids to carboxylates. In this respect, silicones having a pH sensitivity, by virtue of amine or carboxylic acid groups, are known. U.S. Pat. No. 5,447,997 to Releigh et al. teaches silicones containing carboxylic acids whose surface properties change as a function of pH.
The properties of ionic surfactants may not only be changed by pH, but by the nature of the counterions. For example, carboxylates with monovalent counterions such as sodium swell well with water. In contrast, multivalent counterions in the same system, lead to ionic crosslinking and a reduction of swelling. At an interface, the surface activity of such materials are similarly affected by the nature of the counterion.
Multidentate ligands (or “chelating agents”) bind metals very tightly. The classic example is EDTA (ethylenediaminetetraacetic acid). EDTA, normally in its calcium, disodium salt form, is frequently found in food products. Heavy metal ions coming into contact with the EDTA will complex with the amine and carboxylic acid groups, displacing the sodium/calcium ions. The binding efficiency of EDTA and its derivatives is known for many metals and their different oxidation states. Chelating agents are added to many different formulations for different purposes. They have also been bound to polymers. For example, chelating groups similar to those mentioned above are used as supports in affinity chromatography.
However, there still exists a need for silicones that are effective at chelating metal ions using complementary binding, whose properties may be controlled through the relative amounts and morphology of the hydrophilic and hydrophobic blocks, the chelating agent, the pH of the solution, the presence or absence of multivalent counterions, and the specific nature of the multivalent ions.
SUMMARY OF THE INVENTION
The present invention relates to silicone polymers useful as both surfactants and chelating agents. The polymers contain a hydrophobic component (the silicone polymer backbone) and a hydrophilic component. The hydrophilic component may act as a chelating agent; i.e. it will bind a variety of metals. The hydrophilic component may be hydrophilic prior to binding to a metal, or after binding to a metal.
The hydrophobic nature of the silicone is provided by organic radicals, such as methyl or other alkyl groups, modified alkyl groups such as fluoroalkyl groups, aryl groups, and related hydrophobic moieties, bound to the silicon atoms in the polymer. The hydrophilic component includes multiple ligands to cooperatively bind one or more metal centers. Examples of such ligands are well known in the art, and include hydrophilic groups such as carboxylic acids and their derivatives, amines, phosphines, alcohols, and unsaturated systems (multiple bonds) that are or are rendered hydrophilic upon complexation with a metal ion.
In one aspect, the present invention relates to a silicone polymer comprising a hydrophobic polysiloxane backbone and at least one metal binding site which is covalently bound to the hydrophobic polysiloxane backbone, the at least one metal binding site comprising at least two ligands which are optionally bound to a metal.
In one embodiment, at least one of the ligands is hydrophilic either before or after being bound to a metal. The ligand may include groups selected from functional alkyl groups bearing heteroatom-based ligands, functional aryl groups bearing heteroatom-based ligands, functional alkyl groups bearing heteroatom-based ligands where the ligands have exchangeable hydrogen atoms, functional aryl groups bearing heteroatom-based ligands where the ligands have exchangeable hydrogen atoms, functional alkyl groups having &pgr;-ligands, and functional aryl groups having &pgr;-ligands. Preferably, the metal binding sites include two or more carboxylic acids which may act as ligands.
The metal binding site may be covalently bonded to the silicone polymer backbone by a linker, which is at least as stable to hydrolysis as the siloxane linkage in the silicone polymer. The linker may be selected from single atoms including C, N, O, S, or P, or groups including amides, esters, thioesters, urethanes, ureas, alkyl or aryl groups.
The polymers of the invention may have molecular weights from about 500 to about 500,000 g/mol.
In one embodiment, the invention relates to a compound of the formula I:
T
1
(Q
1
)
a
(Q
2
)
b
(Q
3
)
c
T
2
(I)
where a, b and c are independently greater than or equal to 0; and where Q
1
, Q
2
and Q
3
are independently the same or different and are an internal siloxane group of the formula II:
and, where R
4
and R
5
, for each internal siloxane group, are the same or different, and where R
4
and R
5
are independently, H with the proviso that both R
4
and R
5
are not H on the same internal siloxane group, alkoxy, siloxy, alkyl, aryl, functional alkyl, functional aryl, a metal-binding site comprising at least two ligands optionally bound to a metal, or a group having an internal siloxane group of the formula III:
where r is ≧0;
R
7
, and R
8
, are for each internal siloxane group of the formula III the same or different, and R
6
, R
7
, and R
8
are independently, H with the proviso that not more than one of R
6
, R
7
, and R
8
on each internal siloxane group is H, alkoxy, siloxy, alkyl, aryl, functional alkyl, functional aryl, or a metal binding site comprising at least two ligands optionally bound to a metal;
T
1
is a group of the formula (IV):
T
2
is a group of the formula (V):
wherein R
1
, R
2
, R
3
, R
9
, R
10
, R
11
, are independent
Brook Michael A.
Himmeldirk Rodica-Sinziana
Gupta Yogendra N.
Kilpatrick & Stockton LLP
McMaster University
Mruk Brian P.
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