The invention relates to a method for coating a vascular endoprosthesis, wherein the outside of the vascular endoprosthesis is wetted at least partially with a first solution of an active substance, the vascular endoprosthesis is moved in a rotational movement about the longitudinal axis of the vascular endoprosthesis, and a radially acting mechanical force is applied to the outside of the vascular endoprosthesis. The rotational movement has the effect that the solution is carried outward by the centrifugal force, such that no active substance deposits in the interior of the vascular endoprosthesis. The application of a mechanical force to the outside of the vascular endoprosthesis then has the effect of creating crystallization nuclei, such that the active substance can crystallize out.

The present disclosure provides non-aqueous inoculant compositions and methods for enhancing the survival and/or stability of microbial spores in an inoculant composition. In some embodiments, inoculant compositions of the present disclosure comprise microbial spores, one or more dispersants, one or more dust suppressants and a solid non-aqueous carrier.

The present disclosure provides non-aqueous inoculant compositions and methods for enhancing the survival and/or stability of microbial spores in an inoculant composition. In some embodiments, inoculant compositions of the present disclosure comprise microbial spores, one or more dispersants, one or more dust suppressants and a solid non-aqueous carrier.

The present disclosure provides non-aqueous inoculant compositions and methods for enhancing the survival and/or stability of microbial spores in an inoculant composition. In some embodiments, inoculant compositions of the present disclosure comprise microbial spores, one or more dispersants, one or more dust suppressants and a solid non-aqueous carrier.

The present disclosure provides non-aqueous inoculant compositions and methods for enhancing the survival and/or stability of microbial spores in an inoculant composition. In some embodiments, inoculant compositions of the present disclosure comprise microbial spores, one or more dispersants, one or more dust suppressants and a solid non-aqueous carrier.

A construct comprising: (i) an optionally derivatized glycopeptide antibiotic; (ii) a nanoparticle; and (iii) a first linker connecting (i) and (ii) is provided. The construct may further comprise a second linker located between the first linker and (ii). The nanoparticle may be a separation nanoparticle, such as a magnetic separation nanoparticle. The glycopeptide antibiotic may be selected from the group consisting: of vancomycin; teicoplanin; oritavancin; telavancin; chloroeremomycin; and balhimycin. Also provided are related methods of producing and using the construct, such as methods of separation of bacteria from a sample by binding the bacteria to the construct.

A construct comprising: (i) an optionally derivatized glycopeptide antibiotic; (ii) a nanoparticle; and (iii) a first linker connecting (i) and (ii) is provided. The construct may further comprise a second linker located between the first linker and (ii). The nanoparticle may be a separation nanoparticle, such as a magnetic separation nanoparticle. The glycopeptide antibiotic may be selected from the group consisting: of vancomycin; teicoplanin; oritavancin; telavancin; chloroeremomycin; and balhimycin. Also provided are related methods of producing and using the construct, such as methods of separation of bacteria from a sample by binding the bacteria to the construct.

Loose particulate materials can be problematic in various aspects. For example, loose particulate materials may generate dust or be difficult to consolidate together. Fines in loose particulate materials may also be an issue. Coated particulates may alleviate some of the foregoing issues. Suitable coated particulates may comprise a particulate material comprising sand or a ceramic, and a polysaccharide composition coated upon the particulate material, the polysaccharide composition comprising a functionalized polysaccharide. Other particulate materials such as wood chips and animal litter particulates may be coated with functionalized polysaccharides to achieve similar advantages.

Loose particulate materials can be problematic in various aspects. For example, loose particulate materials may generate dust or be difficult to consolidate together. Fines in loose particulate materials may also be an issue. Coated particulates may alleviate some of the foregoing issues. Suitable coated particulates may comprise a particulate material comprising sand or a ceramic, and a polysaccharide composition coated upon the particulate material, the polysaccharide composition comprising a functionalized polysaccharide. Other particulate materials such as wood chips and animal litter particulates may be coated with functionalized polysaccharides to achieve similar advantages.

A coating, a method for coating surfaces, and the coated surfaces. The method includes providing a substrate with a cleaned metal surface; contacting and coating the metal surface with an aqueous composition having a ph of from 0.5 to 7.0 and in the form of a dispersion and/or a suspension; optionally rinsing the organic coating; and drying and/or baking the organic coating, or optionally drying the organic coating and coating same with a similar or another coating composition thereto. The composition contains a complex fluoride in a quantity of 1.1 10.sup.6 mol/l to 0.30 mol/l based on the cations. An anionic polyelectrolyte in a quantity of 0.01 to 5.0 wt % based on the total mass of the resulting mixture is added to an anionically stabilized dispersion made of film-forming polymers and/or a suspension made of film-forming inorganic particles.