The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Y- Lumbar Catheter consists of a F5 (ID: 0.8 mm) radiopaque silicone
The Integra Y- Lumbar Catheter consists of a F5 (ID: 0.8 mm) radiopaque silicone tubing with two open-ended arms (75 mm each) featuring several rows of inlet holes. The Y-shape consists of a 30 degree angle connection between the arms and the drainage catheter. The catheter overall length is 80 cm. A F5 radiopaque silicone Suture Clamp and a F8 -F5 radiopaque polypropylene Stepdown Connector (OD: 1.8 and 1.5 mm; ID: 0.8 mm) are supplied with the catheter.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow Lumbar are implantable hydrocephalu
The Integra Flow Regulating Valves Low Flow Lumbar are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the lumbar subarachnoid region to the peritoneal cavity. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow Lumbar are implantable hydrocephalu
The Integra Flow Regulating Valves Low Flow Lumbar are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the lumbar subarachnoid region to the peritoneal cavity. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hyd
The Integra Flow Regulating Valves Low Flow (Standard, Mini) are implantable hydrocephalus valve systems for controlled cerebrospinal fluid (CSF) drainage from the ventricles to the peritoneal cavity or other appropriate drainage site such as the heart’s right atrium. Unlike conventional valves, the Integra Flow Regulating Valve Low Flow is a variable resistance valve that maintains drainage at a constant rate, between 8 and 17 ml/hr, within the physiological range of intracranial pressure.
The Gravity Compensating Accessory (GCA) is designed to counterbalance gravity’s
The Gravity Compensating Accessory (GCA) is designed to counterbalance gravity’s effects on the fluid column within the drainage catheter of an implanted shunt system. The GCA consists of a silicone elastomer encased stainless steel housing with a ruby ball held in a stainless steel seat (in the vertical orientation) by two to four stainless steel balls. In the horizontal orientation, a minimal resistance to flow (<30mmH2O at 5ml/h) is added to the system, and in the vertical orientation: 140-170, 200-250 or 260-320mmH2O (at 5ml/h).
The Gravity Compensating Accessory (GCA) is designed to counterbalance gravity’s
The Gravity Compensating Accessory (GCA) is designed to counterbalance gravity’s effects on the fluid column within the drainage catheter of an implanted shunt system. The GCA consists of a silicone elastomer encased stainless steel housing with a ruby ball held in a stainless steel seat (in the vertical orientation) by two to four stainless steel balls. In the horizontal orientation, a minimal resistance to flow (<30mmH2O at 5ml/h) is added to the system, and in the vertical orientation: 140-170, 200-250 or 260-320mmH2O (at 5ml/h).
The Gravity Compensating Accessory (GCA) is designed to counterbalance gravity’s
The Gravity Compensating Accessory (GCA) is designed to counterbalance gravity’s effects on the fluid column within the drainage catheter of an implanted shunt system. The GCA consists of a silicone elastomer encased stainless steel housing with a ruby ball held in a stainless steel seat (in the vertical orientation) by two to four stainless steel balls. In the horizontal orientation, a minimal resistance to flow (<30mmH2O at 5ml/h) is added to the system, and in the vertical orientation: 140-170, 200-250 or 260-320mmH2O (at 5ml/h).
The Integra NeuroSciences Ventricular Catheter is a 25 cm silicone elastomer tub
The Integra NeuroSciences Ventricular Catheter is a 25 cm silicone elastomer tubing with full barium impregnation. Numbered length markers are located 5 and 10 cm from the proximal end. Length marker dots are located at 1 cm increments 3 to 14 cm from the proximal end. The proximal end presents fourty (40) flow holes. The proximal tip is constructed of molded, barium sulfate impregnated silicone to provide smooth, consistent end, which aid catheter placement. A stainless steel stylet and a right angle guide are provided.
Connectors are implantable accessories intended to be used with Integra Hydrocep
Connectors are implantable accessories intended to be used with Integra Hydrocephalus Valve Systems for connection between an implanted ventricular catheter or drainage catheter and a CSF Shunt System.
Connectors are implantable accessories intended to be used with Integra Hydrocep
Connectors are implantable accessories intended to be used with Integra Hydrocephalus Valve Systems for connection between an implanted ventricular catheter or drainage catheter and a CSF Shunt System.
Connectors are implantable accessories intended to be used with Integra Hydrocep
Connectors are implantable accessories intended to be used with Integra Hydrocephalus Valve Systems for connection between an implanted ventricular catheter or drainage catheter and a CSF Shunt System.
Connectors are implantable accessories intended to be used with Integra Hydrocep
Connectors are implantable accessories intended to be used with Integra Hydrocephalus Valve Systems for connection between an implanted ventricular catheter or drainage catheter and a CSF Shunt System.
Connectors are implantable accessories intended to be used with Integra Hydrocep
Connectors are implantable accessories intended to be used with Integra Hydrocephalus Valve Systems for connection between an implanted ventricular catheter or drainage catheter and a CSF Shunt System.
The Camino Flex Ventricular Intracranial Pressure Monitoring Kit is indicated wh
The Camino Flex Ventricular Intracranial Pressure Monitoring Kit is indicated when direct and continuous intraventricular intracranial pressure monitoring and cerebrospinal fluid drainage are required. The catheter is embedded with a strain gauge pressure transducer.The system is designed for no more than five days of continuous monitoring.
The Radiopaque Polypropylene Plug consists of a Tubing Plug provided for surgeon
The Radiopaque Polypropylene Plug consists of a Tubing Plug provided for surgeons using the Integral Ventricular Reservoir (IVR) who prefer to use the wire introducer for introduction of the ventricular catheter. The plug allows to close the catheter after its placement.
The Integral Drainage Set (IDS) consists of a one-piece assembly (male Luer-lock
The Integral Drainage Set (IDS) consists of a one-piece assembly (male Luer-lock connector; small diameter drainage inlet tube with attached clamp, check valve, and silicone band; graduated bag with hydrophobic vent filter, drip chamber, suspension string with adjustable clip; large diameter drainage collector; outlet tube with clamp, watertight cap and silicone band); a 360° three-way stopcock with Luer-lock connectors; two stopcock protection boxes.
The External Drainage Set (EDS) consists of: an extension tubing line with a T f
The External Drainage Set (EDS) consists of: an extension tubing line with a T fitting and a four-way stopcock; a one-piece drainage tube assembly, including a patient line with a T fitting, a tubing, an antireflux valve, a 75 ml cylinder and a drainage tubing; a drainage bag with female luer lock connector, a suspension hook and a hydrophobic filter; a 350 mm H2O drainage pressure scale. A Ventricular Catheter Accessory Kit (VCAK). A Pressure Transducer.
The External Drainage Set (EDS) consists of: an extension tubing line with a T f
The External Drainage Set (EDS) consists of: an extension tubing line with a T fitting and a four-way stopcock; a one-piece drainage tube assembly, including a patient line with a T fitting, a tubing, an antireflux valve, a 75 ml cylinder and a drainage tubing; a drainage bag with female luer lock connector, a suspension hook and a hydrophobic filter; a 350 mm H2O drainage pressure scale. A Lumbar Catheter Accessory Kit (LCAK).
6 Drainable Collection Bags, 500 ml, with female Luer-lock connector, a suspensi
6 Drainable Collection Bags, 500 ml, with female Luer-lock connector, a suspension hook, and a hydrophobic filter.
Replacement Drainage Bag, 500 ml, with female Luer-lock connector, a suspension
Replacement Drainage Bag, 500 ml, with female Luer-lock connector, a suspension hook, and a hydrophobic filter.
The External Drainage Set (EDS) consists of: an extension tubing line with a T f
The External Drainage Set (EDS) consists of: an extension tubing line with a T fitting and a four-way stopcock; a one-piece drainage tube assembly, including a patient line with a T fitting, a tubing, an antireflux valve, a 75 ml cylinder and a drainage tubing; a drainage bag with female luer lock connector, a suspension hook and a hydrophobic filter; a 350 mm H2O drainage pressure scale. It also includes a Ventricular Catheter Accessory Kit.
The External Drainage Set (EDS) consists of: an extension tubing line with a T f
The External Drainage Set (EDS) consists of: an extension tubing line with a T fitting and a four-way stopcock; a one-piece drainage tube assembly, including a patient line with a T fitting, a tubing, an antireflux valve, a 75 ml cylinder and a drainage tubing; a drainage bag with female luer lock connector, a suspension hook and a hydrophobic filter; a 350 mm H2O drainage pressure scale.
The CSF Reservoir consists of a silicone dome-shaped reservoir incorporating a p
The CSF Reservoir consists of a silicone dome-shaped reservoir incorporating a polypropylene needle-stop, and an F8 integrated connector. The CSF Reservoir can be provided alone. Other configurations include a right angle ventricular catheter (7 cm or 9 cm length) and a 15 cm introducing rod, or a 15 cm straight ventricular catheter and a right angle guide. The ventricular catheter features radiopaque length markings at 2, 4, 6, 8, 10 cm from the tip.
LKG
PORT & CATHETER, IMPLANTED, SUBCUTANEOUS, INTRAVENTRICULAR
The CSF Reservoir consists of a silicone dome-shaped reservoir incorporating a p
The CSF Reservoir consists of a silicone dome-shaped reservoir incorporating a polypropylene needle-stop, and an F8 integrated connector. The CSF Reservoir can be provided alone. Other configurations include a right angle ventricular catheter (7 cm or 9 cm length) and a 15 cm introducing rod, or a 15 cm straight ventricular catheter and a right angle guide. The ventricular catheter features radiopaque length markings at 2, 4, 6, 8, 10 cm from the tip.
LKG
PORT & CATHETER, IMPLANTED, SUBCUTANEOUS, INTRAVENTRICULAR
The CSF Reservoir consists of a silicone dome-shaped reservoir incorporating a p
The CSF Reservoir consists of a silicone dome-shaped reservoir incorporating a polypropylene needle-stop, and an F8 integrated connector. The CSF Reservoir can be provided alone. Other configurations include a right angle ventricular catheter (7 cm or 9 cm length) and a 15 cm introducing rod, or a 15 cm straight ventricular catheter and a right angle guide. The ventricular catheter features radiopaque length markings at 2, 4, 6, 8, 10 cm from the tip.
LKG
PORT & CATHETER, IMPLANTED, SUBCUTANEOUS, INTRAVENTRICULAR
The OCS2PND is a bipolar stimulating probe for cortical stimulation with malleab
The OCS2PND is a bipolar stimulating probe for cortical stimulation with malleable tips for precise localization. The probe has 2 mm diameter polished balls, spaced 5 mm apart, at the tip of the stimulator probe. It has a 310 cm cord with two electrically shrouded banana plugs for attachment to the OCS2 Ojemann Cortical Stimulator. It is reusable, is supplied non-sterile and must be sterilized before use.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The Auragen™ depth electrodes are designed for intraoperative monitoring of cort
The Auragen™ depth electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are inserted stereotaxically into the brain. Depth electrodes are available with 4 to 12 platinum/iridium contacts. The type of depth electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitor
The AURAGEN™ Cortical Surface Electrodes are designed for intraoperative monitoring of cortical electrical activity in order to define the location of epileptogenic foci. They are placed on the exposed cortical surface or inserted into the subdural space to contact the cortical surface. Cortical Electrodes are available with platinum contacts and vary in size according to the number of contacts. The type of cortical electrode used is dependent on the procedure and the size of area being tested.