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EPstar Fixed Electrophysiology Catheters
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- Overview
- Clinical data
- Technical specifications
- Ordering information
- Training
- Resources
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Enhanced diagnostic precision for coronary sinus mapping and beyond
How it works
EPstar 2F Fixed Electrophysiology Catheter*
The 2F diagnostic microcatheter enables mapping and pacing in distal coronary sinus (CS) branches, which may be inaccessible to other catheters.
EPstar 6F Fixed Electrophysiology Catheter with Lumen†
The 6F diagnostic catheter is torquable with a large lumen, facilitating placement and telescoping of the 2F microcatheter in the coronary venous system.
Using the EPstar 2F Microcatheter*
Enable mapping and pacing in distal coronary venous system branches with the octapolar* 2F microcatheter for deeper diagnostic precision
2F mapping has been used for:
- Idiopathic ventricular tachycardias1,2
- Complex atrial tachycardias3,4
- Left Wolff-Parkinson-White5
- Mapping and pacing in vein of Marshall3,6
Why choose EPstar Fixed Electrophysiology Catheters
Complex diagnostic mapping solutions
What’s included
EPstar Fixed Electrophysiology Catheters and Electrophysiology Cables are sold individually and as solution kits.
EPstar Coronary Venous Mapping Solution
- EPstar 2F Microcatheter*
- EPstar 6F Fixed Catheter with Lumen† (95 cm length)
- Connector cables
EPstar Bundle Kit (555)
- EPstar 2F Microcatheter*
- EPstar 6F Fixed Catheter with Lumen† (5-5-5 mm electrode spacing, 65 cm length)
EPstar Bundle Kit (282)
- EPstar 2F Microcatheter*
- EPstar 6F Fixed Catheter with Lumen† (2-8-2 mm electrode spacing, 65 cm length)
Publication summaries
May 2020, Da-Wariboko et al., scientific session poster published in Heart Rhythm
The EPstar 2F catheter* enabled successful mapping and pacing through small veins to detect activation patterns, characterize epicardial signals, and verify ethanol induced ablation.
EPstar Fixed Electrophysiology Catheter - 2F
Feature | Specifications |
French size | 2F |
Electrodes | 8 octapolar |
Usable length | 130 cm |
Electrode spacing | 5-5-5 mm |
Electrode size | 1.3mm Distal tip: 1.5 mm |
EPstar Fixed Electrophysiology Catheter with Lumen - 6F
Feature | Specifications |
French size | 6F |
Electrodes | 10 (65 cm), 11 (95 cm) |
Usable length | 65 cm, 95 cm |
Electrode spacing | 5-5-5 mm, 2-8-2 mm (65 cm)
5-5-5 mm decapolar, additional indifferent electrode 220 mm from distal tip (95 cm) |
Electrode size | 1.2mm |
EPstar Fixed Electrophysiology Cables
Feature | Specifications |
Usable length | 2.3 meters |
Number of pins | 10, 14 |
Number of uses | Single use or 5 uses |
Ordering information
Product type | Product | Electrode spacing | Product code |
---|---|---|---|
Diagnostic catheters | EPstar 2F Fixed Electrophysiology Catheter | 5-5-5 mm | DCF-2-8-55-130 |
EPstar 6F Fixed Electrophysiology Catheter with Lumen (95 cm) | 5-5-5 mm | DLF-6-10-55-95R | |
EPstar 6F Fixed Electrophysiology Catheter with Lumen (65 cm) | 5-5-5 mm 2-8-2 mm | DLF-6-10-55-65 DLF-6-10-28-65 | |
Solution kits | EPstar Coronary Venous Mapping Solution
| 5-5-5 mm | DLFK0007 |
EPstar Bundle Kits
| 6F: 5-5-5 mm 6F: 2-8-2 mm | DLK-2-55-6-55-65 DLK-2-55-6-28-65 | |
Cables | Electrophysiology Cable (10 pins, resterilizable - 5 uses) | N/A | DEX-10 |
Electrophysiology Cable (14 pins, single use) | N/A | DEX-14 |
Looking for more training? Contact our medical education team
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Brochures
Publications
* EPstar Fixed Electrophysiology Catheter
† EPstar Fixed Electrophysiology Catheter with Lumen
References
- Komatsu, Y., et al. (2018). Idiopathic ventricular arrhythmias originating from the vicinity of the communicating vein of cardiac venous systems at the left ventricular summit. Circ Arrhythm Electrophysiol, 11(1). doi: 10.1161/CIRCEP.117.005386
- Ito, S., et al. (2005). Simultaneous mapping in the left sinus of valsalva and coronary venous system predicts successful catheter ablation from the left sinus of valsalva. Pacing Clin Electrophysiol, 28(s1). doi: 10.1111/j.1540-8159.2005.00081.x
- Kawamura, I., et al. (2019). Characteristics of Marshall bundle-related atrial tachycardias using an ultrahigh-resolution mapping system. J Interv Card Electrophysiol, 55(2), 161-169. doi: 10.1007/s10840-019-00544-9
- Yamamoto, T., et al. (2014). Marshall bundle reentry: A novel type of macroreentrant atrial tachycardia. Heart Rhythm, 11(7), 1229-1232. doi: 10.1016/j.hrthm.2014.03.051
- Davis, L., et al. (1995). Simultaneous mapping of the tricuspid and mitral valve annuli at electrophysiological study. Br Heart J, 73(4), 377-382. doi: 10.1136/hrt.73.4.377
- Fujisawa, T., et al. (2019). Importance of the vein of Marshall involvement in mitral isthmus ablation. Pacing Clin Electrophysiol, 42(6), 617-624. doi: 10.1111/pace.13640