ITBS20020029U1 - FIBER OPTIC CATHETER FOR THERMAL-ABLATION - Google Patents

Description

HIESSE s.r.l

DESCRIPTION

of the PATENT for INDUSTRIAL UTILITY MODEL entitled:

"FIBER OPTIC CATHETER FOR THERMO - ABLATION" in the name of FOGAZZI di Venturelli Andrea & C. S.n.c., of Italian nationality, with headquarters in Via L. Marenzio 7 - Loc. Roncaglie, 25062 CONCESIO, Brescia Application No. „.. ^ ΛDeposit on 5 »5 MfìP

ÌlBS2OS: U0t0U29

The present utility model generally relates to fiber optic catheters for use in the medical and surgical field, and refers in particular to a fiber optic catheter for thermo-ablation by las In the field of medical and surgical devices currently There are also known catheters for carrying out thermo-ablation operations in various parts or organs of a body which can be reached through natural ducts or lumens. There are also known fiber optic catheters for the average thermal ablation of laser beams. In these catheters, the optical fibers extend in length

of the catheter from a proximal connector that can be connected to a laser machine up to a distal end where the optical fibers are exposed for the irradiation of the part to be treated.

However, in such an embodiment, the desired irradiation occurs through the free ends of the optical fibers and is essentially directed only frontally, forward beyond the distal part of the catheter. Some thermo-ablation interventions using laser beams may instead require essentially radial irradiation, in the form of a circular crown around the catheter, an action that known catheters are not able to perform.

3 miLaaL · s.i.i.

The present invention is aimed at remedying such a deficiency. In fact, its main purpose is to provide a catheter with a particular and innovative combination of functional elements that allows a predominantly radial irradiation for thermo-ablation treatments to be carried out around the catheter. Another object of the invention is to provide a catheter capable of additionally receiving at least one optical fiber for thermal ablation laser irradiation, including frontal.

Said purposes and the implicit advantages deriving from them are achieved with an optical fiber catheter connectable to a laser source, in which the distal ends of the optical fibers are truncated obliquely and complementarily associated with a reflecting surface defined by an ogival tip placed at the end. thimble of the catheter, so that the laser rays that travel through the optical fibers are reflected laterally outwards from the catheter itself.

The catheter may or may not be traversed by a longitudinal hole. When present, such a hole can possibly be used to insert and move a guide wire or to house at least one additional optical fiber for irradiation also in front of the catheter.

Further details of the invention will in any case become evident from the rest of the present description made with reference to the accompanying drawings, indicative and not limiting, in which:

Fig. 1 shows an overall view of an optical fiber catheter; Fig. 2 shows, enlarged, a side view of the distal part of the catheter of Fig. 1;

Fig 3 shows a further enlarged longitudinal section of the distal part of the catheter shown in Fig. 2;

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Fig. 4 shows a cross section according to the arrows A - A on Fig. 2 of a four-fiber catheter;

Fig. 5 shows a similar cross section of a six-fiber optic catheter; And

Fig. 6 shows a cross section at the level of the metal tip according to the arrows B - B on Fig. 2.

The catheter proposed here comprises a flexible central element 11, extending in length along a longitudinal axis, around which optical fibers 12 are parallel arranged, the quantity of which can be chosen at will. In the examples of Figs. 4 and 5, the optical fibers are four and six in number, respectively.

The central element 11 can have a solid section, but more preferably tubular so as to define a longitudinal hole 13.

The optical fibers 12 extend from a proximal end 14 to near a distal end 15 of the central element 11. They are peripherally enclosed in a flexible containment sheath 16 and can be stabilized in their position with a filling material or binder, such as a resin, placed between the sheath and the fibers themselves.

At the proximal end 14 the optical fibers 12 can be connected through a connector 17 to a laser radiation generating machine - not shown.

In the vicinity of their distal part 15, the optical fibers 12 are surrounded by a locking ring 18 which can be, for example, in platinum or gold and in any case in a suitable material compatible with the destination and use of the catheter. In their distal part 15, the optical fibers 12,

BIESSE s.r.l.

beyond the locking ring 18, they have a portion exposed to the outside and are cut at an angle, to result in an oblique terminal 19. As shown in Fig. 3, the oblique terminal 19 of each optical fiber is inclined from external towards the axis of the central element and associated with a facing reflecting surface 20 which is also inclined. This reflecting surface 20 is defined by a metal tip 21, of ogival shape or similar, fixed to the distal end of the central element 11.

Therefore, the laser radiations that travel through the optical fibers 12 are reflected and emitted laterally towards the outside of the catheter, at the distal end of this, around it, irradiating the surrounding part to be treated by thermo-ablation.

The angle of inclination of the oblique terminal 19 of each optical fiber 12 and correspondingly of the reflecting surface 20 can be chosen at will according to the total or partial reflection to be obtained. Such an angle of inclination can be the same for all the optical fibers of the same catheter or it can vary for some optical fibers with respect to others, so as to orient the laser beam emission field differently in response to the irradiation needs of the part to be treated.

When the catheter is crossed longitudinally by a hole 13, this can be used to pass a guide wire through it or even to house at least one additional optical fiber, this not shown, with its own terminal in front of the tip to correspond to irradiation needs. , where useful, also on the front of the catheter for a frontal thermal ablation.

Claims (9)

mussi !, s.r.i, CLAIMS 1. Optical fiber catheter for laser thermo-ablation, comprising a flexible longitudinal central element (11) and a plurality of optical fibers (12), running externally along the central element between a proximal end connectable to a source of laser radiation and a distal end and enclosed in a peripheral sheath (16) with the interposition of a possible filling material or binder, characterized in that the distal ends of the optical fibers (12) are truncated on the bias defining an oblique terminal (19) for each of them, and in that the oblique terminals of the optical fibers are associated with a facing reflecting surface (20 defined by a metal tip (21) at the distal end of the catheter, so that the laser beams traveling through the optical fibers are reflected laterally towards the outside of the catheter. 2. Optical fiber catheter according to claim 1, in which the oblique terminal (19) of the optical fibers (12) is inclined from the outside towards the center of the central element (11) in the direction from the front to the rear of the catheter and is associated with the reflecting surface (20) inclined likewise, the angle of inclination of said oblique terminal and of the reflecting surface being chosen according to a total reflection or partial laser beams. 3. Optical fiber catheter according to claims 1 and 2, in which the angle of inclination of the oblique terminal (19) is the same for all optical fibers. 4. Optical fiber catheter according to claims 1 and 2, in which the angle of inclination of the oblique terminal is different from some optical fibers compared to others. 7 BIESSE s.r.l. Optical fiber catheter according to any one of the preceding claims, in which the optical fibers (12) are surrounded and blocked by a peripheral ring (18) in proximity to their oblique terminal (19) leaving a space for radial remission of the laser beams reflexes. 6. Optical fiber catheter according to any one of the preceding claims, in which the metal tip (21) is of an ogival shape and fixed to an extreme part of the longitudinal central element. Optical fiber catheter according to any one of the preceding claims, wherein said longitudinal central element (11) has a solid section. Optical fiber catheter according to any one of claims 1 to 6, wherein said central element (11) defines a longitudinal hole (13) for the passage of a guide wire or for receiving at least one additional optical fiber with one end distal emitting in front of the tip. 9. Fiber optic catheter for thermo-ablation, as substantially described above, illustrated and claimed for the specified purposes. B.