A modular unit configured for mounting to a cutting head of a slicing machine and for securing a knife to the cutting head, and slicing machines equipped with one or more of such modular units. The modular unit includes mounting blocks adapted to be spaced apart in an axial direction of the cutting head, and a clamping assembly assembled with the mounting blocks so as to extend between the mounting blocks. The clamping assembly is configured to secure a knife to the cutting head, and at least portions of the clamping assembly may be removable from the cutting head by disassembling the clamping assembly from the mounting blocks without removing the mounting blocks from the cutting head.

A modular unit configured for mounting to a cutting head of a slicing machine and for securing a knife to the cutting head, and slicing machines equipped with one or more of such modular units. The modular unit includes mounting blocks adapted to be spaced apart in an axial direction of the cutting head, and a clamping assembly assembled with the mounting blocks so as to extend between the mounting blocks. The clamping assembly is configured to secure a knife to the cutting head, and at least portions of the clamping assembly may be removable from the cutting head by disassembling the clamping assembly from the mounting blocks without removing the mounting blocks from the cutting head.

The present invention is a kit to be used for obtaining Adipose tissue-based stem cells, which especially is suitable for obtainment of Adipose tissue-based stem cells, which comprises a reservoir (1) through which the entrance of the adipose tissue, that is taken from a predetermined area of the individual, into the kit; characterized by comprising a first housing (2), which is located on the said reservoir (1) and enables the transmission of the adipose tissue into the kit, a second housing (3), which is located on the said reservoir (1) and which enables the second injector (40) to be positioned outside the reservoir (1) and in a perpendicular position to the reservoir (1), a third housing (4) which enables the third injector (50) to be positioned outside the reservoir (1) and in a perpendicular position to the reservoir (1), an empty body (6) which is fixed inside the reservoir (1), a first inlet (7) which enables the transmission of the adipose tissue into the body (6) by pushing of the injector, a passage (8) which can rotate its own axis and which enables the circulation of the adipose tissue that is inside the body (6) between a desired inlet inside the body (6) and another inlet which is positioned in a 90 degree angle to this inlet by this rotation movement, at least one cover (10) which enables the said movement of the passage (8) and covers the top of the reservoir (1), a second inlet (12) which comprises a first splitting element (11) that is obtained by alignment of a multiple of cutting elements (10), and a third inlet (14) which comprises at least one second splitting element (13) which enables the adipose tissue split when it enters to and exits from the injector and is obtained by alignment of a multiple of cutting elements (10).

The present invention is a kit to be used for obtaining Adipose tissue-based stem cells, which especially is suitable for obtainment of Adipose tissue-based stem cells, which comprises a reservoir (1) through which the entrance of the adipose tissue, that is taken from a predetermined area of the individual, into the kit; characterized by comprising a first housing (2), which is located on the said reservoir (1) and enables the transmission of the adipose tissue into the kit, a second housing (3), which is located on the said reservoir (1) and which enables the second injector (40) to be positioned outside the reservoir (1) and in a perpendicular position to the reservoir (1), a third housing (4) which enables the third injector (50) to be positioned outside the reservoir (1) and in a perpendicular position to the reservoir (1), an empty body (6) which is fixed inside the reservoir (1), a first inlet (7) which enables the transmission of the adipose tissue into the body (6) by pushing of the injector, a passage (8) which can rotate its own axis and which enables the circulation of the adipose tissue that is inside the body (6) between a desired inlet inside the body (6) and another inlet which is positioned in a 90 degree angle to this inlet by this rotation movement, at least one cover (10) which enables the said movement of the passage (8) and covers the top of the reservoir (1), a second inlet (12) which comprises a first splitting element (11) that is obtained by alignment of a multiple of cutting elements (10), and a third inlet (14) which comprises at least one second splitting element (13) which enables the adipose tissue split when it enters to and exits from the injector and is obtained by alignment of a multiple of cutting elements (10).

An apple peeler and corer is configured with a main body having a platform which is raised above a lower foundation for the main body. A crank handle drives a threaded rod toward a blade assembly for slicing an apple. A rocker arm carries a peeler blade and may be resiliently biased toward the blade assembly or locked in a position pivoted away from the blade assembly.

An apple peeler and corer is configured with a main body having a platform which is raised above a lower foundation for the main body. A crank handle drives a threaded rod toward a blade assembly for slicing an apple. A rocker arm carries a peeler blade and may be resiliently biased toward the blade assembly or locked in a position pivoted away from the blade assembly.

A pusher for use with a mandoline slicer includes a cap having an upper and a lower end, the cap defining an interior space. A lower plate is attached to a pillar, which is attached to a telescoping post. The pillar and telescoping post are telescopically moveable with respect to one another along the central axis and trained for movement by a guide within the cap. Stops are provided along the guide to restrict the length of travel of the telescoping post and pillar. A spring is connected to the cap and the lower plate to urge the lower plate away from the cap in a direction from the upper end toward the lower end.

A pusher for use with a mandoline slicer includes a cap having an upper and a lower end, the cap defining an interior space. A lower plate is attached to a pillar, which is attached to a telescoping post. The pillar and telescoping post are telescopically moveable with respect to one another along the central axis and trained for movement by a guide within the cap. Stops are provided along the guide to restrict the length of travel of the telescoping post and pillar. A spring is connected to the cap and the lower plate to urge the lower plate away from the cap in a direction from the upper end toward the lower end.

Disclosed herein is an apparatus for removing material from a surface of a carrier. The apparatus comprises a buckling mechanism that comprises a gripper configured to engage the material. When engaged with the material, the gripper is movable relative to the surface of the carrier to move the material relative to the surface of the carrier and to form a buckle in the material. The apparatus also comprises a separation mechanism that is coupled to the buckling mechanism and comprises a wedge that is movable relative to the surface of the carrier to be insertable into the buckle formed in the material.

A tissue splitting device for splitting a harvested soft tissue to provide a layer of tissue having a uniform thickness and methods for tissue transplantation using uniform layers of tissue.