A telescoping catheter is provided such as for distal neurovascular aspiration or access. The catheter includes an elongate, flexible tubular body, having a proximal section with at least one lumen and a distal section which is axially movably positioned within the lumen. A control is provided for advancing the distal section from a first, proximally retracted position within the proximal section to a second extended position, extending distally beyond the proximal section. The distal end of at least one of the proximal and distal sections may be provided with at least one active feature, such as at least one movable jaw or rotatable agitator, to assist in the capture of vascular obstruction. The jaw may be operable in response to application of pulsatile negative pressure through the catheter.

A press for making a continuous sheet from composite material has upper and lower press belts having respective lower and upper reaches that vertically spacedly confront one another across a press gap having an upstream inlet end and a downstream outlet end, and that have transversely spaced outer edges extending in the direction. The belts are advanced direction and thereby draw a mat of the composite material in the inlet end, compress it into the sheet, and expelling the sheet from the downstream end. Two transversely spaced elastic seal strips extend in the direction in the gap and are each engaged between a respective one of the outer edges of the upper belt and the respective outer edge of the lower belt. Each belt has at each of the edges a surface in engagement with the respective edge strip and having an average peak-to-valley height of less than 1 m.

Systems and methods for applying a protective layer to an outer surface of a mobile device. A system may include a protective layer for an outer surface of a mobile device and an alignment layer coupled to the protective layer. A frame may define a cavity configured to receive the mobile device. The frame may include a surface positioned outside of the cavity and configured to support the alignment layer and configured to be depressed relative to the mobile device to reduce a distance between the protective layer and the outer surface of the mobile device when the mobile device is positioned in the cavity.

Systems and methods for applying a protective layer to an outer surface of a mobile device. A system may include a protective layer for an outer surface of a mobile device and an alignment layer coupled to the protective layer. A frame may define a cavity configured to receive the mobile device. The frame may include a surface positioned outside of the cavity and configured to support the alignment layer and configured to be depressed relative to the mobile device to reduce a distance between the protective layer and the outer surface of the mobile device when the mobile device is positioned in the cavity.

Systems and methods for applying a protective layer to an outer surface of a mobile device. A system may include a protective layer for an outer surface of a mobile device and an alignment layer coupled to the protective layer. A frame may define a cavity configured to receive the mobile device. The frame may include a surface positioned outside of the cavity and configured to support the alignment layer and configured to be depressed relative to the mobile device to reduce a distance between the protective layer and the outer surface of the mobile device when the mobile device is positioned in the cavity.

A screen protector laminate applicator is used with an installation machine to install a screen protector on a mobile device. The laminate applicator comprises a web secured to the installation machine; the screen protector carried by the web, and a backing layer covering the screen protector opposite the web. The web, the screen protector and the backing layer are removably coupled together as a laminate. A tab of the backing layer extends beyond the perimeter of the screen protector and comprises an enlarged head connected to the backing layer by a narrower neck.

A method of aspirating a vascular occlusion from a remote site is provided. The method includes the steps of advancing a first elongate tubular body through a vascular access site and into a body vessel, advancing a second tubular body distally to extend beyond the first elongate tubular body to reach the remote site, and aspirating thrombus from the site into the lumen by applying pulsatile vacuum to the first elongate tubular body. The second tubular body has a lumen and a length that is shorter than the first elongate tubular body. The pulsatile application of vacuum may cause the distal tip of the second tubular body to open and close like a jaw, which facilitates reshaping the thrombus or biting or nibbling the thrombus material into strands or pieces to facilitate proximal withdrawal under negative pressure through the lumen of the second tubular body.

A sheet laminate that can be easily affixed to a bonded surface and which can enhance handleability. The sheet laminate (1) includes a pair of sidewall parts (3), each extending toward the rear surface (2b) side from a pair of mutually opposing edges of the main body part (2). The pair of sidewall parts 3 have a curved shape projecting outward with respect to the main body part (2). Including such a sidewall part (3) makes it possible to affix the sheet laminate (1) to the B-pillar (50) by sandwiching the side surfaces (50b) of both sides of the B-pillar (50) having a bonded surface (50a) by using the curved shape of the pair of sidewall parts (3) while covering the bonded surface (50a) with the design surface of the main body part (2). As a result, the sheet laminate (1) can be affixed easily to the bonded surface (50a), which enhances handleability of the sheet laminate (1).

Self-guiding cutting tool (100) for cutting an adhesive film (20) applied to the roof panel (30) of a car, wherein the roof panel is connected to a side panel (31) of the car by a joint area (32) containing a welding ditch channel, said cutting tool (100) comprising a cutting device (6), at least one guiding means (2) guiding the cutting device (6) over the welding ditch channel of the joint area (32), and at least one transporting means (3) allowing the cutting device (6) to be moved over the welding ditch channel of the joint area (32). Also provided is a method of applying adhesive films to the roof panels of a car using the cutting tool.

To provide an insole more easily fitting to a purchaser's foot. A method for manufacturing an insole comprises: a first step of foaming a footprint resin portion 12 having a footprint shape having a predetermined thickness using a thermoplastic resin which melts at a predetermined temperature; a second step of performing shrink processing such that the footprint resin portion 12 is covered with a film, and thereafter vacuum packing the footprint resin portion covered with the film in a nylon polyethylene bag; a third step of heating the insole 10 manufactured through the first step and the second step at a predetermined temperature; and a fourth step of attaching the insole 10 having the footprint resin portion 12 melt by the third step to the inside of a shoe 2 of a user, and hardening the footprint resin portion 12 by leaving the shoe 2 stand for a predetermined time period while the user is wearing the shoe 2.