Abstract: A microcapsule includes an active component encapsulated within a polymerized hydrolyzed protein shell. The microcapsule has an average diameter that is less than one hundred micrometers as determined by a laser diffractometer.

Abstract: A microcapsule includes an active component encapsulated within a polymerized hydrolyzed protein shell. The microcapsule has an average diameter that is less than one hundred micrometers as determined by a laser diffractometer.

Abstract: A microcapsule includes an active component encapsulated within a polymerized hydrolyzed protein shell. The microcapsule has an average diameter that is less than one hundred micrometers as determined by a laser diffractometer.

Abstract: A process for producing microencapsulates comprising an active component such as creatine encapsulated within a polymerized hydrolyzed whey protein matrix is described. The method comprises the steps of providing a suspension of hydrolyzed whey protein and an active component in a carboxylic ester, treating the suspension to generate droplets of the suspension, and immediately curing the droplets by immersion in a basic curing solution, wherein the ester in the suspension reacts with the basic curing solution to release a salt that polymerizes the hydrolyzed whey protein encapsulating the active component in the presence of black pepper extract, glycerol, phosphate and optionally, astaxanthin and alpha lipoic acid.

Abstract: A method for producing microbeads comprising an active component encapsulated within a gelled polymer matrix comprises the steps of providing a suspension of denatured whey protein and an active component, treating the suspension to generate microbeads, and immediately curing the microbeads by acidification. The microbeads are discrete droplets of gelled whey protein having an average diameter in the micron range (for example, from 80 to 500 microns) and which suitably have a generally spherical shape. The microbeads are capable of surviving passage through the stomach, and delivering the encapsulated active agent in the intestine. Ex-vivo and in-vivo data shows that active agent encapsulated within microbeads retains its functionality upon delivery to the intestine, and that coating of the microcapsules allows targeted delivery of the active agent to the distal part of the intestine.

Abstract: A process for producing microencapsulates comprising an active component such as creatine encapsulated within a polymerised hydrolysed whey protein matrix is described. The method comprises the steps of providing a suspension of hydrolysed whey protein and an active component in a carboxylic ester, treating the suspension to generate droplets of the suspension, and immediately curing the droplets by immersion in a basic curing solution, wherein the ester in the suspension reacts with the basic curing solution to release a salt that polymerises the hydrolysed whey protein encapsulating the active component in the presence of black pepper extract, glycerol, phosphate and optionally, astaxanthin and alpha lipoic acid.

Abstract: A method for producing microbeads comprising an active component encapsulated within a gelled polymer matrix comprises the steps of providing a suspension of denatured whey protein and an active component, treating the suspension to generate microbeads, and immediately curing the microbeads by acidification. The microbeads are discrete droplets of gelled whey protein having an average diameter in the micron range (for example, from 80 to 500 microns) and which suitably have a generally spherical shape. The microbeads are capable of surviving passage through the stomach, and delivering the encapsulated active agent in the intestine. Ex-vivo and in-vivo data shows that active agent encapsulated within microbeads retains its functionality upon delivery to the intestine, and that coating of the microcapsules allows targeted delivery of the active agent to the distal part of the intestine.

Abstract: A method for producing microbeads comprising an active component encapsulated within a gelled polymer matrix comprises the steps of providing a suspension of denatured whey protein and an active component, treating the suspension to generate microbeads, and immediately curing the microbeads by acidification. The microbeads are discrete droplets of gelled whey protein having an average diameter in the micron range (for example, from 80 to 500 microns) and which, suitably have a generally spherical shape. The microbeads are capable of surviving passage through the stomach, and delivering the encapsulated active agent in the instestine. Ex-vivo and in-vivo data shows that active agent encapsulated within microbeads retains its functionality upon delivery to the intestine, and that coating of the microcapsules allows targeted delivery of the active agent to the distal part of the intestine.

Abstract: A method for producing microbeads comprising an active component encapsulated within a gelled polymer matrix comprises the steps of providing a suspension of denatured whey protein and an active component, treating the suspension to generate microbeads, and immediately curing the microbeads by acidification. The microbeads are discrete droplets of gelled whey protein having an average diameter in the micron range (for example, from 80 to 500 microns) and which, suitably have a generally spherical shape. The microbeads are capable of surviving passage through the stomach, and delivering the encapsulated active agent in the instestine. Ex-vivo and in-vivo data shows that active agent encapsulated within microbeads retains its functionality upon delivery to the intestine, and that coating of the microcapsules allows targeted delivery of the active agent to the distal part of the intestine.