Interventional Cardiology. Группа авторов. Читать онлайн. Newlib. NEWLIB.NET

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Издательство: John Wiley & Sons Limited
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Жанр произведения: Медицина
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isbn: 9781119697381
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      Inflation of an adequately sized balloon at low pressure (3–6 atmospheres) in a proximal branch can augment support by anchoring the guide catheter to the vessel and the branch (Figure 5.6) [9]. Low inflation pressures are essential to reduce the risk of dissection or damage to a small right ventricular branch or diagonal/marginal branch. In these branches, ischemia resulting from prolonged inflation is well tolerated. The technique is mostly used in treating CTO and is facilitated by a large guide catheter.

Schematic illustration of components of guidewire design.

      Adjunctive techniques

      Double coaxial guiding catheter technique (also known as mother–child)

      The Kiwami® 4 Fr‐in‐6 Fr catheter measures 120 cm, 1.43mm (outer diameter) 1.27mm (inner diameter); the inner layer is coated with polytetrafluoroethylene (PTFE) and the surface is coated with a hydrophilic surface up to 15 cm from the tip of the catheter. The backstream prevention valve (Terumo) is connected to the guide catheter of 6 or 7 Fr. The conventional Y‐connector is attached to Kiwami® (child) which was inserted in the 6 or 7 Fr (mother) catheter. Because the effective length of Kiwami® is 120 cm, the projected length from the mother catheter differs depending on the length of mother catheter used [12]. The 4 Fr‐in‐6 Fr Kiwami® catheter is probably the most deliverable among the GC extensions, but has the smallest lumen (0.050 inch) and requires meticulous attention to details to avoid air embolism [13].

      Guide catheter extensions

      In the GuideLiner® catheter (Teleflex‐Vascular Solutions, Maple Grove, MN, USA) a coaxial short distal soft catheter is mounted at the tip of a long stainless‐steel rod, which extends outside the guide catheter. This enables deep intubation of the coronary artery to achieve extra support and improve coaxial alignment. It has a coaxial 20 cm long catheter with a radiopaque marker situated 2.7 mm from the tip from the tip, joined to a 125 cm compact metal hypotube by means of a ring (“collar”, made of metal in the first version and replaced by a lubricious polymer in the V2 version), which can be deployed through the existing Y‐adapter for rapid exchange delivery. The device is available in three sizes: 5‐in‐6 (0.056 inch internal diameter (ID)), 6‐in‐7 (0.062 inch ID), and 7‐in‐8 (0.071 inch ID). Its monorail design permits rapid exchange and offers important advantages over its predecessors, the “five‐in‐six mother and child” catheters Heartrail II®, which had a coaxial system that made their utilization more demanding [11]. Furthermore, rapid exchange helps with deployment through the existing hemostatic valve without extending the guiding catheter length, and so does not limit the useable length of balloons and wires. Other Companies designed similar catheters such as the Guidezilla™ (Boston Scientific, Marlbourough, MA, USA), Telescope (Medtronic, Minneapolis, MN, USA), Gideon (IVS, Maastricht, The Netherlands), claiming more lubricious coatings or smoother connections between hypotube and distal catheter. The Guidezilla is probably the most widely used guide extension after the GuideLiner, is mounted on a monorail system, which extends the guide catheter and enables deep intubation of the coronary artery. It is made of a distal end of 25 cm covered by a hydrophilic polymer, joined to a 120‐cm compact metal hypotube. The distal flexible extension consists of a pair of radiopaque markers, the first situated 2 mm from the tip and the second 3 mm from the transition collar. The device is available in one size 5‐in‐6 and compatible with guide catheter ≥6 Fr. An additional system, with sizes compatible also with 5 Fr guiding catheters, is the Guidion rapid exchange guide extension catheter (IMVS, Roden, the Netherlands).

      De Man et al. [14], published results from the Twente GuideLiner Registry identifying three primary indications for the use of the device: improvement of back‐up and facilitated stent delivery (59%), more selective contrast injection (13%), and improvement of alignment of the guide (29%). Moreover, they found a device and procedural success rate of 93% and 91%, respectively, without major complications and a small incidence of minor complications (3%). The safety and efficacy of utilizing the GuideLiner monorail catheter to treat complex lesions was confirmed in recent experience published by Chan et al and Fabris et al. [15,16], showing good performance of the device in the settings of bypass graft intervention, bifurcation lesions, and chronic total occlusions. In order to avoid damage of the proximal vessel, especially in case of non‐coaxial alignment of the coronary ostium and extreme proximal vessel tortuosity (e.g. a shepherd’s crook’s origin of the RCA”), a balloon advanced distally can be used to reduce the chance of damaging the ostium and the proximal vessel by acting as centering rail). If the guide extension does not advance this can be caused by vessel tortuosity and poor GC back‐up and solved inflating the distal balloon to gently attract it or can be caused by presence of proximal stenoses or calcifications, in need of effective predilatation.

      Guidewires are required to cross the target lesion and to provide support for the delivery of balloons, stents, and other devices while at the same time minimizing the risk of vessel trauma. A guidewire needs to be steerable, visible, flexible, lubricious, and supportive. There is no single wire that has the perfect combination of all these characteristics. Variations in guidewire components have produced a wide range of wires suitable for different anatomies and lesion characteristics. Wire selection depends on which features are thought to optimally facilitate angioplasty for a given clinical and angiographic scenario.

      Guidewires typically