Abstract: The present invention embraces a manually operated arrangement (“A”) and a method, adaptable for a transfer along a longitudinal extension of a rail (1) and intended to be able to secure said rail to a subjacent crosstie (2) by a horizontal transfer of clips (3: 3a), included in fastening elements (4), and displaceably oriented in relation to a holder (5) included in the fastening element (4), where the holder (5, 5a) co-operates firmly with said crosstie (2). The respective one of said clips (3; 3a) is adapted to, by a movement, allow displacing the clips (3: 3a) horizontally for a clamping of the rail base (1c) in relation to the holder (5). An opposed first pair (6a, 6b) of a first lever-shaped means (6) is adapted to, via its lower end areas (6aa, 6ab) co-operate with the clips. For this purpose, the invention provides a means (20, 21, 23) lifting the crosstie (2) with holders (5) and clips (3) up to the rail base, which means is adapted adjustable in height (“D”).

Abstract: The present invention embraces a manually operated arrangement (“A”) and a method, adaptable for a transfer along a longitudinal extension of a rail (1) and intended to be able to secure said rail to a subjacent crosstie (2) by a horizontal transfer of clips (3: 3a), included in fastening elements (4), and displaceably oriented in relation to a holder (5) included in the fastening element (4), where the holder (5, 5a) co-operates firmly with said crosstie (2). The respective one of said clips (3; 3a) is adapted to, by a movement, allow displacing the clips (3: 3a) horizontally for a clamping of the rail base (1c) in relation to the holder (5). An opposed first pair (6a, 6b) of a first lever-shaped means (6) is adapted to, via its lower end areas (6aa, 6ab) co-operate with the clips. For this purpose, the invention provides a means (20, 21, 23) lifting the crosstie (2) with holders (5) and clips (3) up to the rail base, which means is adapted adjustable in height (“D”).

Abstract: The method is for monitoring biological data in a human body. A sensor senses biological data from a human body and sends the biological data to a control unit that sends the biological data to a communicator. The communicator compares the biological data to triggering values. The communicator only transmits the biological data when the triggering values have been exceeded by the biological data. The communicator sends an alert signal including the biological data in a dedicated bandwidth to a server. A decision rule engine analyzes the biological data and decides which message to send and to which recipient based on the biological data. A medical institution pays a fee to a service unit for accessing the system.

Abstract: A device (1), e.g. an intravascular device, for removing an element, e.g. vascular occluding element (33), from within a lumen, e.g.

Abstract: The method is for monitoring biological data in a human body. A sensor senses biological data from a human body and sends the biological data to a control unit that sends the biological data to a communicator. The communicator compares the biological data to triggering values. The communicator only transmits the biological data when the triggering values have been exceeded by the biological data. The communicator sends an alert signal including the biological data in a dedicated bandwidth to a server. A decision rule engine analyzes the biological data and decides which message to send and to which recipient based on the biological data. A medical institution pays a fee to a service unit for accessing the system.