Abstract: A prosthetic device (1) adapted for the carriage of fluids therethrough within a human or animal body and to be placed in or replace a curved lumen. The prosthetic device has a control arrangement to control the length of one side with respect to the other side so that the device can be curved insitu to fit the curved lumen. The control arrangement can be an expansion restriction arrangement or a length reduction arrangement. The prosthesis can be stented or unstented and be formed from a tubular or corrugated material.

Abstract: A stent graft deployment device adapted for release of a distal end (29) of a stent graft (25) before the proximal end (27) of the stent graft (25). The arrangement (15) allows movement of at least part of the deployment catheter (23) independently of movement of a proximal end release mechanism has a fixed handle (16) associated with a trigger wire release mechanism (6) and a sliding handle (17) to which the deployment catheter and a capsule (21) are fixed. The sliding handle (17) is mounted on the fixed handle (16) and can slide longitudinally with respect to the fixed handle (16).

Abstract: An introduction arrangement for a fenestrated or branched stent graft (13) intended for deployment into the lumen of a vessel having a blind vessel extending from it. The introducer (1) has a distal end intended to remain outside a patient in use and a proximal end with a nose cone dilator (11) and an arrangement to retain the branched stent graft distally of the nose cone dilator. A sheath (15) on the introducer extends over the branched stent graft to the nose cone dilator. An indwelling catheter (22) extends from the distal end of the introducer and enters the fenestration or side arm and through to the nose cone dilator, the indwelling catheter has a guide wire (29) extending through it. The guide wire can be extended beyond the nose cone dilator in use before the sheath is withdrawn from the branched stent graft so that it can be snared from the contra-lateral artery.

Abstract: A mould assembly (60) and a method of use in injection moulding of a part having a functional cavity therein. The mould assembly has a recess (72) to receive a hollow tubular insert (48) intended to be placed in the mould assembly before the injection of a mouldable material into the cavity and to remain in the part after moulding. A gas supply arrangement supplies pressurised gas to the hollow tubular insert at a selected stage during the injection process whereby to form the functional cavity in the part.

Abstract: An ovum collection device (20) includes a handle (4) and a collection needle (3) extending from the handle. The collection needle has a sharpened tip (44) for insertion into a follicle of an ovary. A collection duct (5) in fluid communication with the collection needle extends from the handle to a collection bottle (6). A heating arrangement (14) is used to maintain the collection needle at a selected temperature to prevent damage to an oocyte. The heating arrangement may be associated with a needle guide (72) on an ultrasonic probe such as a transvaginal ultrasonic probe (70).

Abstract: A composite stent graft has a balloon expandable stent portion (3), a tubular graft material portion (1) inside or outside of the balloon expandable stent portion and self expanding stents (5) associated with the tubular graft material portion. Part (7) of the balloon expandable stent portion can extend beyond the proximal end (9) of the tubular graft material portion. The tubular graft material can be polytetrafluoroethylene, Dacron, Thoralon™, polyamide, small intestine submucosa, collagenous extracellular matrix material, or any other suitable biocompatible material. A method of deploying which includes flaring a part (7) of the balloon expandable stent portion is also discussed.

Abstract: A stent arrangement which has at least a first ring (3) and zig zag struts (5) extending axially from the periphery of the ring. There can be first and second rings (3, 4) axially spaced apart and defining substantially parallel planes and a plurality of zig zag portions (5) between the first and second ring portions around the periphery thereof. The stent can be formed from a single wire or laser cut from a cannula and can be covered or uncovered.

Abstract: A stent graft (20) has a tubular body of graft material (21), a number of self expanding stents (67) associated with the tubular body to define a fluid flow path through the stent graft when the self expanding stents are in their expanded configurations. At least one fenestration (22) in the tubular body is adapted to receive a side arm stent graft (71) to provide a fluid flow path from the tubular body and through the side arm stent graft. The or each fenestration has at least an inner ring (26) and an outer ring (24) and graft material (28) extending from the inner ring to the outer ring and the outer ring being in the tubular body of graft material. The inner ring can be hinged (31) to the outer ring or concentric within the outer ring. An intermediate ring (86) may also be used between the inner and outer rings.

Abstract: A stent graft (1) including a tubular wall (3) with at least one fenestration (40) including a peripheral (37) reinforcement around at least part of the fenestration. There can also be a tubular extension (15). The side arm includes a stent (19) and a cover (17) and extends from and is in fluid communication with the fenestration and the stent graft. The stent may be a self expanding stent. The ring and/or tubular extension provides better support and sealing for an extension arm. The fenestration (40) can be circular or if towards the ends of the stent graft may be in the form of a U-shape (50) with an open end.

Abstract: A bung for an aspiration assembly sample collection tube, the bung (1) has a top surface (3), a tapered side surface (7) for fitting into the sample tube and a lower surface (5). First and second apertures (9, 11) extend through the bung from the top surface to the bottom surface, the first aperture (9) being for an inlet tubing and the second aperture (11) being for an aspiration tubing, the first aperture has a recess (13) in the lower surface of the bung. This recess is adapted to sealingly receive a supply nozzle of a flushing fluid supply device such as a syringe so that in use flushing fluid may be directed through the inlet tubing.

Abstract: An access valve (2) for a laparoscopic device or a intraluminal deployment device has a cylindrical diaphragm (8) with a longitudinal aperture (3), a flexible member (14) is passed circumferentially around the cylindrical diaphragm and an extension arrangement to pull the flexible member radially and/or tangentially to constrict the diaphragm to at least partially close off the longitudinal aperture. A rotary actuator may be used (12).

Abstract: A deployment system for introducing stent grafts which have a side arm or into which a side arm can be deployed. For instance the stent graft can be deployed into the thoracic arch of a patient. The deployment system including an introducer (1), an auxiliary catheter (13) disposed within the introducer and an auxiliary guide wire (14) disposed within the auxiliary catheter. The auxiliary guide wire extends to adjacent the proximal end (6) of the introducer an can be extended from the proximal end of the introducer so that it can be snared from a side branch artery (56) to assist with deployment of a side arm (23) of the stent graft into the side artery or for the deployment of a side arm stent graft into the stent graft.

Abstract: An aspiration and flushing needle assembly having separable flushing and aspiration assemblies. The flushing assembly (2) has a flushing needle (27) extending from a handle (25) and a flushing fluid line (35) which can be connected to a source of flushing liquid. The aspiration assembly (1) has an aspiration needle (5) with a connector (9) which connects into the rear of the handle and an aspiration line (13) which can be connected to an aspiration arrangement. The flushing and aspiration needle assemblies are joined for use with the aspiration needle extending coaxially within the flushing needle to the distal end (29) of the flushing needle.

Abstract: A prosthesis, introducer device and a method for repair of an aortic aneurysm which is positioned at least partially in the ascending aorta (62). The prosthesis (3) has a proximal end (15) and a distal end (5) and is formed from a biocompatible material, the proximal end is adapted to be surgically fastened adjacent and around the aortic heart valve (60) of a patient and the distal end is adapted to extend into the descending aorta (66). The distal end has a distally extending exposed self-expanding stent (9). The introducer device can be deployed through an incision (75) in the thoracic arch (64) and extend down the descending aorta to place the distal end of the prosthesis first and then removed so that the proximal end of the prosthesis can be sutured in place around the aortic heart valve (60).

Abstract: A prosthesis adapted for inter-luminal placement by endovascular deployment for the treatment of vascular dissection, the prosthesis has a self expanding stents (38) connected together to define an elongate lumen wall engaging surface. At least one of the stents has a biocompatible graft material cover (36) to define a covered portion (25). The cover is adapted to close off a rupture (7) in the wall of the lumen (6) and the stents are adapted to provided pressure on the wall of the lumen adjacent to and extending away from the rupture.

Abstract: A thoracic stent graft (20) has a tubular bio-compatible graft material body (22) with a lumen therethrough with a proximal end (26) and a distal end (27). There is a sealing stent (28) at the proximal end of the tubular body with an anchoring device which may be a barb (30) affixed to the sealing stent. A distal attachment stent (34) with barbs (36) can be affixed to and extend from the distal end (27) of the graft material body. Intermediate stents (24) are provided along the length of the body. The thoracic stent graft can be in one or two portions.

Abstract: A stent graft deployment apparatus (10) which has a deployment catheter (11) with a proximal end (5) to be introduced into a patient and a distal end (3) to remain outside a patient and at a proximal end thereof a region to contain a stent graft (21). A sheath (25) extends over and covers the stent graft and can be moved to expose the stent graft to enable deployment of the stent graft. A nose cone dilator (17) is positioned at the proximal end of the deployment catheter and can be curved. A capsule (40) provides a distal retention arrangement for the stent graft.

Abstract: An endoluminal stent graft deployment system useful for deployment of a limb of a branched stent graft (16) into a blind vessel. The branched stent graft has a main body (16) and a limb (19) extending from the body. The branched stent graft is mounted on a deployment device which has a separate deflecting guide wire (14) extending into the limb. The method of deploying the branched stent graft into a blind vessel in a human or animal body includes the step of releasing the limb from the deployment device, extending the guide wire from the limb into the blind vessel, manipulating the deployment device by withdrawing the deployment device slightly to cause the limb to enter the blind vessel assisted by the guide wire and releasing the stent graft from the deployment device.

Abstract: A stent graft deployment device adapted for release of a distal end (29) of a stent graft (25) before the proximal end (27) of the stent graft (25). The arrangement (15) allows movement of at least part of the deployment catheter (23) independently of movement of a proximal end release mechanism has a fixed handle (16) associated with a trigger wire release mechanism (6) and a sliding handle (17) to which the deployment catheter and a capsule (21) are fixed. The sliding handle (17) is mounted on the fixed handle (16) and can slide longitudinally with respect to the fixed handle (16).

Abstract: A prosthesis assembly for deployment in an aorta to span an aortic aneurysm. The prosthesis assembly has at least first and second members (2,4) with an end portion (12) of one member (2) to be joined to an end portion (24) of the other member (4) when in and when expanded within a lumen of a patient. Each member (2,4) has a stent arrangement (10,25) associated with a graft arrangement (8,26). The end portion of one member has at least part of its stent arrangement on the inner surface of its graft arrangement and the end portion of the other member has at least part of its stent arrangement on the inner surface of its graft arrangement. Advantageously two stents are overlapped. The joining portions of the first and second members can have the same diameter.