A modulated guanidine substituted polymer or nanoparticle has a guanidine moiety or on a plurality of repeating units of a polymer or on the surface of a nanoparticle where the guanidine moiety is modulated as a substituted amidinourea or amidinocarbamate or salt thereof. The modulated guanidine substituted polymer or nanoparticle can be prepared by direct amination of a N-Boc protected guanidine substituted conjugated polymer or N-Boc protected guanidine substituted nanoparticle, where an amine or alcohol is combined in solution or suspension with the protected conjugated polymer or nanoparticle and the resulting mixture is heated. The modulated guanidine substituted polymer or nanoparticle can be used in a cancer treatment formulation.

A modulated guanidine substituted polymer or nanoparticle has a guanidine moiety or on a plurality of repeating units of a polymer or on the surface of a nanoparticle where the guanidine moiety is modulated as a substituted amidinourea or amidinocarbamate or salt thereof. The modulated guanidine substituted polymer or nanoparticle can be prepared by direct amination of a N-Boc protected guanidine substituted conjugated polymer or N-Boc protected guanidine substituted nanoparticle, where an amine or alcohol is combined in solution or suspension with the protected conjugated polymer or nanoparticle and the resulting mixture is heated. The modulated guanidine substituted polymer or nanoparticle can be used in a cancer treatment formulation.

A method for producing molding sand includes mixing an artificial sand with a furan resin composition including a furan resin precursor, and mixing a curing agent with the artificial sand with which the furan resin composition is mixed, wherein the curing agent includes xylene sulfonic acid.

A method for producing molding sand includes mixing an artificial sand with a furan resin composition including a furan resin precursor, and mixing a curing agent with the artificial sand with which the furan resin composition is mixed, wherein the curing agent includes xylene sulfonic acid.

A modulated guanidine substituted polymer or nanoparticle has a guanidine moiety or on a plurality of repeating units of a polymer or on the surface of a nanoparticle where the guanidine moiety is modulated as a substituted amidinourea or amidinocarbamate or salt thereof. The modulated guanidine substituted polymer or nanoparticle can be prepared by direct amination of a N-Boc protected guanidine substituted conjugated polymer or N-Boc protected guanidine substituted nanoparticle, where an amine or alcohol is combined in solution or suspension with the protected conjugated polymer or nanoparticle and the resulting mixture is heated. The modulated guanidine substituted polymer or nanoparticle can be used in a cancer treatment formulation.

A modulated guanidine substituted polymer or nanoparticle has a guanidine moiety or on a plurality of repeating units of a polymer or on the surface of a nanoparticle where the guanidine moiety is modulated as a substituted amidinourea or amidinocarbamate or salt thereof. The modulated guanidine substituted polymer or nanoparticle can be prepared by direct amination of a N-Boc protected guanidine substituted conjugated polymer or N-Boc protected guanidine substituted nanoparticle, where an amine or alcohol is combined in solution or suspension with the protected conjugated polymer or nanoparticle and the resulting mixture is heated. The modulated guanidine substituted polymer or nanoparticle can be used in a cancer treatment formulation.

To provide a process for producing a fluorinated polymer having a cyclic structure at a relatively low cost, by efficiently recovering, from a mixture containing a fluorinated polymer obtained by polymerizing a perfluoromonomer having a cyclic structure and an unreacted perfluoromonomer having a cyclic structure, the unreacted perfluoromonomer having a cyclic structure. A monomer component containing a perfluoromonomer having a specific cyclic structure is polymerized in the presence of a polymerization initiator at a predetermined polymerization temperature to obtain a mixture containing a fluorinated polymer and an unreacted cyclic structure monomer, and the perfluoromonomer having a cyclic structure is recovered from the mixture at a temperature of at most the maximum ultimate temperature of the polymerization temperature+12 C. and at most the 10 hour half-life temperature of the polymerization initiator+12 C. under a pressure of less than the atmospheric pressure.

To provide a process for producing a fluorinated polymer having a cyclic structure at a relatively low cost, by efficiently recovering, from a mixture containing a fluorinated polymer obtained by polymerizing a perfluoromonomer having a cyclic structure and an unreacted perfluoromonomer having a cyclic structure, the unreacted perfluoromonomer having a cyclic structure. A monomer component containing a perfluoromonomer having a specific cyclic structure is polymerized in the presence of a polymerization initiator at a predetermined polymerization temperature to obtain a mixture containing a fluorinated polymer and an unreacted cyclic structure monomer, and the perfluoromonomer having a cyclic structure is recovered from the mixture at a temperature of at most the maximum ultimate temperature of the polymerization temperature+12 C. and at most the 10 hour half-life temperature of the polymerization initiator+12 C. under a pressure of less than the atmospheric pressure.

To provide a monomer composition in which the solubility of the polymerization inhibitor in the cyclic monomer is good, the stability of the cyclic monomer during storage is good, and the cyclic monomer and the polymerization inhibitor are easily separated by distillation; and a method for producing a high molecular weight fluorinated polymer from the monomer composition.

A monomer composition which comprises a specific cyclic monomer and a polymerization inhibitor, wherein the polymerization inhibitor is a polymerization inhibitor which satisfies (a) it is a 6-membered unsaturated cyclic hydrocarbon having from 1 to 4 substituents, (b) it has, as the substituent, at least one type selected from the group consisting of a t-butyl group, a methyl group, an isopropenyl group, an oxo group and a hydroxy group, (c) in a case where it has an oxo group as one type of the substituent, it has, as the substituent other than the oxo group, either one or both of a t-butyl group and a methyl group, and (d) in a case where it has a hydroxy group as the substituent, the number of the hydroxy group is only one.

The composition for film formation includes a compound including a group of the formula (1) and a solvent. In the formula (1), R.sup.1 to R.sup.4 each independently represent a hydrogen atom, a monovalent organic group having 1 to 20 carbon atoms, or R.sup.1 to R.sup.4 taken together represent a cyclic structure having 3 to 20 ring atoms together with the carbon atom or a carbon chain to which R.sup.1 to R.sup.4 bond. Ar.sup.1 represents a group obtained by removing (n+3) hydrogen atoms from an aromatic ring of an arene having 6 to 20 carbon atoms. n is an integer of 0 to 9. R.sup.5 represents a hydroxy group, a halogen atom, a nitro group, or a monovalent organic group having 1 to 20 carbon atoms.

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