<p>Precise navigation of a guidewire tip to a target within the three-dimensional (3D) structure of a coronary artery—controlled from 140&#xa0;cm away—requires “3D wiring,” a technique involving wire manipulation based on 3D imaging. Hypothesizing that 3D wiring enables the standardization of wiring techniques for chronic total occlusion (CTO) intervention, we have established a 3D wiring method utilizing fluoroscopy and intravascular ultrasound (IVUS). As a first step to visualize guidewire movement within CTO lesions, we collaborated with Terumo Corporation to develop the Navifocus WR in 2012, a CTO-specific IVUS featuring a small diameter and a short tip. Observing guidewire movement during CTO PCI using this IVUS provided the insights necessary to understand how the shaft and tip must be visualized to facilitate effective 3D wiring. We first established angiography-guided 3D wiring using “3D imaging rules” in 2014. Subsequently, to achieve real-time IVUS-guided 3D wiring, we devised the tip detection (TD) method in 2017 and developed the AnteOwl WR IVUS (Terumo Corporation)—a short-tip, pullback-compatible catheter—in 2019, establishing a strategic approach for TD-intra-plaque tracking. Contrary to the traditional view that IVUS guidance is limited to intra-plaque tracking, our 2021 findings show that re-entry is routinely feasible through TD-guided perpendicular puncture (TD-ADR: Antegrade Dissection and Re-entry). This evolution elevated the TD method into a more robust technique for wire crossing. This review aims to systematically organize the theory of 3D wiring and disseminate this knowledge to the global community.</p>

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Angiography- and IVUS-tip-detection-guided 3D wiring for CTO and non-CTO percutaneous coronary interventions

  • Atsunori Okamura,
  • Ryohei Yoshikawa,
  • Kota Tanaka,
  • Satoshi Suzuki,
  • Masato Ishikawa,
  • Hiroyuki Nagai,
  • Tomohiro Yamasaki,
  • Kazunori Yamaji,
  • Katsutoshi Kawamura,
  • Naotaka Okamoto,
  • Takayuki Ishihara,
  • Wataru Nagamatsu,
  • Takeshi Serikawa,
  • Yoshiaki Ito,
  • Heitaro Watanabe

摘要

Precise navigation of a guidewire tip to a target within the three-dimensional (3D) structure of a coronary artery—controlled from 140 cm away—requires “3D wiring,” a technique involving wire manipulation based on 3D imaging. Hypothesizing that 3D wiring enables the standardization of wiring techniques for chronic total occlusion (CTO) intervention, we have established a 3D wiring method utilizing fluoroscopy and intravascular ultrasound (IVUS). As a first step to visualize guidewire movement within CTO lesions, we collaborated with Terumo Corporation to develop the Navifocus WR in 2012, a CTO-specific IVUS featuring a small diameter and a short tip. Observing guidewire movement during CTO PCI using this IVUS provided the insights necessary to understand how the shaft and tip must be visualized to facilitate effective 3D wiring. We first established angiography-guided 3D wiring using “3D imaging rules” in 2014. Subsequently, to achieve real-time IVUS-guided 3D wiring, we devised the tip detection (TD) method in 2017 and developed the AnteOwl WR IVUS (Terumo Corporation)—a short-tip, pullback-compatible catheter—in 2019, establishing a strategic approach for TD-intra-plaque tracking. Contrary to the traditional view that IVUS guidance is limited to intra-plaque tracking, our 2021 findings show that re-entry is routinely feasible through TD-guided perpendicular puncture (TD-ADR: Antegrade Dissection and Re-entry). This evolution elevated the TD method into a more robust technique for wire crossing. This review aims to systematically organize the theory of 3D wiring and disseminate this knowledge to the global community.