A rheolytic system for percutaneous coronary and peripheral plaque removal

A method for plaque dissolution has been identified that percutaneously delivers a pulsatile high-velocity stream of saline to the site of an atheromatous lesion within a coronary or peripheral artery. In vitro evaluation and in vivo canine and porcine testing were performed using this 'rheolyt...

Full description

Saved in:
Bibliographic Details
Published inAngiology Vol. 42; no. 2; p. 90
Main Authors Drasler, W J, Jenson, M L, Wilson, G J, Thielen, J M, Protonotarios, E I, Dutcher, R G, Possis, Z C
Format Journal Article
LanguageEnglish
Published United States 01.02.1991
Subjects
Animals
Arteriosclerosis - therapy
Catheterization - instrumentation
Catheterization - methods
Coronary Artery Disease - therapy
Dogs
Femoral Artery
Humans
In Vitro Techniques
Pressure
Sodium Chloride - administration & dosage
Swine
Online AccessGet more information

Cover

More Information
Summary:A method for plaque dissolution has been identified that percutaneously delivers a pulsatile high-velocity stream of saline to the site of an atheromatous lesion within a coronary or peripheral artery. In vitro evaluation and in vivo canine and porcine testing were performed using this 'rheolytic' system to determine its feasibility in ablating calcified plaque and soft thrombotic tissue. A prototype rheolytic guidewire capable of providing 30,000 psi of internal pressure was designed to fit within the guidewire lumen of a standard percutaneous transluminal coronary angioplasty catheter. An additional over-the-wire rheolytic catheter was fabricated to follow a standard .014-inch guidewire. The rheolytic devices were tested in vitro with simulated atheromatous and thrombotic lesions to evaluate the size and quantity of the particulate effluent. The particulate was then sterilized, mixed with saline, and introduced percutaneously into the animal kidney and heart for evaluation. The in vitro studies demonstrated that the rheolytic catheter and guidewire were able to follow both a coronary and femoral arterial model and successfully ablate the simulated lesions. The particle size for osseous, muscular, and cartilagenous tissue ranged from 2 to 6 micrometers; for fresh human plaque the particles ranged from 2 to 15 micrometers. Injection of cartilagenous and plaque particles into the animal model caused very slight regions of necrosis but no clinical sequelae. Applications of the rheolytic devices to the animal femoral artery demonstrated that both devices could ablate and cross calified or soft thrombosed lesions without damage to the vessel wall; the rheolytic catheter provided a debulking of the plaque.
ISSN:0003-3197
DOI:10.1177/000331979104200202