Abstract: A device configured to mechanically remove a fat phase from at least one adipose tissue includes a first pressing element and a second pressing element. Furthermore, a method for preparing a preparation including a fat-depleted adipose tissue, comprises mechanically removing a fat phase from at least one adipose tissue. In addition, there is provided a preparation including a fat-depleted adipose tissue, wherein the fat-depleted adipose tissue is prepared by mechanically removing a fat phase from at least one adipose tissue.

Abstract: A scaffold is provided, the scaffold comprising: at least one inlet tube; at least one outlet tube; and a plurality of porous elongated microtubes, wherein each one of said porous elongated microtube has an inner diameter of 5-100 micrometers, wherein said plurality of elongated microtubes extend from said at least one inlet tube to said at least one outlet tube and is in fluid communication thereto, Further provided is a method for producing and using the scaffold, such a s for tissue engineering.

Abstract: A device configured to mechanically remove a fat phase from at least one adipose tissue includes a first pressing element and a second pressing element. Furthermore, a method for preparing a preparation including a fat-depleted adipose tissue, comprises mechanically removing a fat phase from at least one adipose tissue. In addition, there is provided a preparation including a fat-depleted adipose tissue, wherein the fat-depleted adipose tissue is prepared by mechanically removing a fat phase from at least one adipose tissue.

Abstract: A device for treating an artificial bone implant with blood, the device comprising: a container configured to accommodate an artificial bone implant and be filled with blood, wherein the container comprises an opening and a cover configured to cover the opening of the container. Additional embodiments of the device and methods for using the same are disclosed herein.

Abstract: A device configured to mechanically remove a fat phase from at least one adipose tissue includes a first pressing element and a second pressing element. Furthermore, there is provided a method for preparing a preparation including a fat-depleted adipose tissue, the method including mechanically removing a fat phase from at least one adipose tissue. In addition, there is provided a preparation including a fat-depleted adipose tissue, wherein the fat-depleted adipose tissue is prepared by mechanically removing a fat phase from at least one adipose tissue.

Abstract: A scaffold is provided, the scaffold comprising: at least one inlet tube; at least one outlet tube; and a plurality of porous elongated microtubes, wherein each one of said porous elongated microtube has an inner diameter of 5-100 micrometers, wherein said plurality of elongated microtubes extend from said at least one inlet tube to said at least one outlet tube and is in fluid communication thereto, Further provided is a method for producing and using the scaffold, such as for tissue engineering.

Abstract: The present invention provides a device configured to mechanically remove a fat phase from at least one adipose tissue, the device comprising a first pressing element and a second pressing element. Furthermore, there is provided a method for preparing a preparation comprising a fat-depleted adipose tissue, the method comprising: mechanically removing a fat phase from at least one adipose tissue. In addition, there is provided a preparation comprising a fat-depleted adipose tissue, wherein the fat-depleted adipose tissue is prepared by mechanically removing a fat phase from at least one adipose tissue.

Abstract: A device for treating an artificial bone implant with blood, the device comprising: a container configured to accommodate an artificial bone implant and be filled with blood, wherein the container comprises an opening; and a cover configured to cover the opening of the container. Additional embodiments of the device and methods for using the same are disclosed herein.

Abstract: A scaffold is provided, the scaffold comprising: at least one inlet tube; at least one outlet tube; and a plurality of porous elongated microtubes, wherein each one of said porous elongated microtube has an inner diameter of 5-100 micrometers, wherein said plurality of elongated microtubes extend from said at least one inlet tube to said at least one outlet tube and is in fluid communication thereto, Further provided is a method for producing and using the scaffold, such as for tissue engineering.

Abstract: A porous scaffold is disclosed, the porous scaffold comprising electrospun polymeric nanofibers, wherein an average diameter of a pore of the porous scaffold is about 300 ?m is disclosed. An average diameter of the polymeric nanofibers ranges from about 100 to 400 nm. The scaffold may comprise a plurality of particles, the particles being greater than about 1 ?m in diameter. Methods of fabricating scaffolds, methods for generating tissue and methods of using scaffolds for tissue reconstruction are also disclosed.

Abstract: Articles of manufacturing comprising electrospun elements having continuous or stepwise gradients of porosity, average pore size, weight per volume and/or of agents for promoting cell colonization, differentiation, extravasation and/or migration are provided. Also provided are methods of manufacturing and using same for guiding tissue regeneration.

Abstract: A porous scaffold is disclosed, the porous scaffold comprising electrospun polymeric nanofibers, wherein an average diameter of a pore of the porous scaffold is about 300 ?m is disclosed. An average diameter of the polymeric nanofibers ranges from about 100 to 400 nm. The scaffold may comprise a plurality of particles, the particles being greater than about 1 ?m in diameter. Methods of fabricating scaffolds, methods for generating tissue and methods of using scaffolds for tissue reconstruction are also disclosed.

Abstract: Articles of manufacturing comprising electrospun elements having continuous or stepwise gradients of porosity, average pore size, weight per volume and/or of agents for promoting cell colonization, differentiation, extravasation and/or migration are provided. Also provided are methods of manufacturing and using same for guiding tissue regeneration.

Abstract: A method of repairing a long bone having a defect is provided. The method includes the steps of: (a) mechanically fixating the long bone or portions thereof; and (b) filling the defect with a biodegradable scaffold impregnated with growth factors and/or osteoprogenitor cells and awaiting for osteointegration to take place.

Abstract: A dental implant that comprises a generally rod-like article formed with one or more hollow(s) therein and a biodegradable hydrogel containing one or more bone growth-promoting agent(s) in the hollow(s) is disclosed. A method of implanting the dental implant and a method of sinus augmentation prior to implanting a dental implant are further disclosed.

Abstract: A method of repairing a long bone having a defect is provided. The method includes the steps of: (a) mechanically fixating the long bone or portions thereof; and (b) filling the defect with a biodegradable scaffold impregnated with growth factors and/or osteoprogenitor cells and awaiting for osteointegration to take place.