DE8806359U1 - Trocar sleeve for laser beam application - Google Patents

Description

PATENT ATTORNEY DlPL-1NQ. J, WEN ₁ IqL ; 7» ^TUlrtüAftT.'HftOPTMANNSREUTE 46

Karl Storz GmbH & Co, T-Jettlingen

Trocar sleeve for laser beam application

The invention relates to a trocar sleeve for laser beam application according to the preamble of claim 1.

The known trocars are preferably used for operations in the abdominal or thoracic cavity. First, a so-called sharp trocar mandrel is inserted into the trocar sleeve and introduced into the body cavity together with it. The sharp mandrel is then pulled out of the sleeve, whereby a valve arranged in the trocar sleeve usually closes automatically. Then an operating instrument or an insufflation sleeve is inserted into the trocar sleeve with a blunt end instead of the sharp mandrel. Then, for example, the air pressure inside the body cavity can be measured through a jacket tube that is designed to be easily detachable from the trocar sleeve. The jacket tube can also be provided with a flange that has a thread or a bayonet lock for screwing the trocar sleeve (DE-GM 75 13 482).

There are also known endoscopes in which a laser beam is additionally arranged in the periscope. The laser beam is arranged at an angle to the periscope and

PATENT ATTORNEY DIPL.-ING. J. WENZEL 7 STUTTGART HAUPTMANNSREUTE 46

penetrates this in a window. A deflection mirror is now provided within the beam path, which is permeable to the visible light, while all infrared frequencies beyond this are deflected by the mirror, as is the laser beam. This means that the endoscope optics can be used for the laser beam, which makes it possible to use the laser beam and observe at the same time.

In another embodiment, the periscope and the laser beam are arranged in separate tubes that are parallel to one another within the endoscope shaft. This also makes it possible to observe the laser beam at the same time. In this case, a movable deflection mirror is arranged at the end of the tube for the laser beam closest to the patient. However, this has the disadvantage that the diameter of the endoscope shaft is increased because two different tubes for different purposes have to be accommodated in it. (US-PS 4,141,362).

A laser probe for an endoscope is also known in which air or carbon dioxide gas is introduced into an outer tube that surrounds the probe at a distance, which is suitable for various

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PATENT ATTORNEY . DIPL-ING. J.WENZEL· 7STUTTQAnT HAUPTMANN8REUTE 46

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This has proven to be effective in various medical treatments . Among other things, it can prevent the laser beams from being scattered at the irradiation end face of the light guide, thus avoiding the formation of diffuse light (DE-OS 34 36 508).

Finally, a catheter with a drive and optics for laser beam application is also known, in which several drive nozzles are arranged near the lens, through which a pressure medium is passed against the intended drive direction, which can be a phytosanitary saline solution. Here it is possible to exchange the tube for the laser beam conductor for an endoscope with an optical phase and a fluorescent phase for illumination. Thus, the requirement for equilateral observation is missing here (DE-PS 35 12 018).

Furthermore, an obturator with a rounded closure plug is known for closing the opening of endoscope shafts near the patient for the purpose of safely introducing them into body cavities (DE-PS24 18 901).

The invention is based on the object of designing the trocar sleeve of the type mentioned at the beginning in such a way that, in contrast to

PATENT ATTORNEY DIPL-ING. J. WENZEL 7 STUTTGART HAUPTMANNSREUTE 4&bgr;

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the state of the art means that the endoscope shaft does not have to be inserted. This means that the trocar sleeve can have a small diameter and a sharp trocar mandrel is not required, but the sleeve can be inserted into the patient's body through a small incision.

To solve this problem, the characterizing features of claim 1 are provided. This makes it possible to use the full cross-section of the periscope for the passage of the laser radiation and at the same time for the passage of gas.

To further solve the problem, the features of claim 6 are provided. Due to the stepped or conical design, such a trocar sleeve can be introduced into the body cavity more ^easily than before.

Advantageous embodiments of the two solutions are contained in subclaims 2-5 and 7.

Further advantages and details can be found in the following description of some embodiments with reference to the drawing. In this, you can see:

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PATENT ATTORNEY DIPL-ING. J. WENZEL 7 STUTTGART HAUPTMANNSREUTE 46

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Fig. 1 is a side view of the first embodiment with inserted obturator;

Fig.2 the same as Fig.l, but with the obturator pulled out;

Fig. 3 is a side view of the obturator according to the first embodiment on its own;

Fig. 4 is a side view of another embodiment;

Fig. 5 is a side view of a further embodiment and

Fig. 6 is a side view of a fourth embodiment.

Fig. 1 shows on the left the end of the trocar sleeve remote from the patient with the obturator inserted and screwed to the trocar sleeve, the handling flange 7 of which can be seen on the left side . The corresponding bayonet catch 9 cannot be seen here, since it is screwed to the IM11s? «, which can be rotated about the axis , through the nipple 10 .

The details of such a bayonet closure are known, for example for screwing sharp trocorts into the sleeve, and therefore do not need to be explained in more detail to the person skilled in the art.

Further to the right you can see a connector 1 with a connection to a gas such as carbon dioxide. On the right is the middle area of the inventive

PATENT ATTORNEY DIPL-ING. J. WENZEL 7 STUTTGART HAUPTMANNSREUTE 46

- 6, which should remain free inside to allow the gas to pass through.

At the end closest to the patient, you can see a side window 4 in the trocar sleeve, which also serves as an outlet for the gas. Further to the right, an oblique deflection mirror 3 is arranged in dotted lines, through which the laser beam and the optical beam can be guided out to the side.

Finally, the end 6 closest to the patient is blunt so that it can be safely inserted into a body cavity.

It can also be seen that window 4 is closed by the obturator.

Fig. ? shows the same trocar sleeve with the obturator 5 pulled out. For this purpose, the bayonet locking sleeve 0 was rotated by 90 ° around the axis using the nipple 10 and the flange 7 was pulled out to the left as shown in Fig. 1.

Furthermore, one can see in Fig. 2 that the middle area 2 of the trocar sleeve is completely free on the inside, for which reason the wall of this middle area has been shown in section.

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PATENT ATTORNEY DIPL-INaJ-WENZEL 7 STUTTGART HAUPTMANNSREUTE

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You can now also see the window 4 without the inserted obturator 5 at the right end closest to the patient, to which the deflection mirror 3 or another lens is connected at the blunt end 6 closest to the patient.

Finally, Fig. 3 shows the obturator 5 on its own. The actuating flange 7 and the bayonet catch have already been mentioned and are formed in one piece with each other together with the remaining elongated part, which adjoins the end closest to the patient. On this one can see the inclined surface 12, which is aligned with the inclined surface of the deflection mirror 3 according to Figs. 1 and 2 , so that after actuation of the bayonet catch, contamination of the mirror 3 during the insertion of the trocar sleeve into the body cavity is reliably prevented .

To prevent the deflection mirror 3 from becoming dirty, the total length of the obturator is dimensioned so that it does not touch the mirror when screwed on. On the other hand, it is also possible to provide the end of the obturator closest to the patient with a soft material such as foam rubber, which then touches the deflection mirror 3 or another lens, but under no circumstances has a scratching effect.

PATENT ATTORNEY OIPL-iNG. J. WsJgkl»' 7 buTTgART _T .H*UPTMANNSREUTE_46

There are now a large number of other, not shown, embodiments. For example, the window 4 can be formed by a glass or plastic window, as is usual with endoscopes. In this case, an additional exit opening (not shown) or several exit openings are required at the end 6 closest to the patient. In this case, the obturator 5 can be omitted because the deflection mirror 3 is protected by the closed window.

The bayonet lock sleeve 8 can then be used exclusively to connect the trocar sleeve according to the invention to an endoscope.

In the embodiment shown, the object of the invention is inserted into the body cavity in the form shown in Fig. 1, i.e. with the obturator 5 screwed on. If it is not a natural body cavity, the doctor can first make an incision for this purpose in order to then be able to insert the blunt end 6 safely. After insertion into the body cavity, the obturator 5 is pulled out after turning the bayonet locking ring 8 and an endoscope is inserted or its lens is attached to the sleeve using the bayonet locking ring 8. For this, the endoscope must of course be adapted to the sleeve, which affects both the optical beam path and the laser beam angle to the deflection device 3 or another lens.

PATENT ATTORNEY DIPL-INQ. J.WENZEL 7 STUTTGART HAUPTMANNSREUTE 4&bgr;

This is easily understandable to the expert, which follows from the requirement that the middle area 2 should be kept free of any built-in components.

It is advantageous that this central region 2 is mirrored on the inside, which prevents heating by the laser beam.

The subject of the invention has the great advantage that the diameter of the trocar sleeve can be made extremely small because the tube required for the beam path can be fully used at the same time for the passage of the gases. Air, like carbon dioxide, is a gas that does not or hardly obstructs the beam path, at least not at the distances that are relevant here.

This is also due to the fact that no endoscope shaft is required in the area of the trocar sleeve according to the invention. Instead, the invention allows the trocar sleeve itself to serve as the endoscope shaft.

This is also the case with the other embodiments according to Figs. 4, 5 and 6.

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PATENT ATTORNEY DIPL.-INQ. J. WENZEL 7 STUTTGART HAUPTMANNSREUTE 4P

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Fig. 4 shows a stepped shaft 13, the individual steps 17, 18, 19, 20 and 21 of which decrease in diameter towards the end closest to the patient. A correspondingly thin obturator 5a is provided here, the end closest to the patient protruding to the right from the last step 21. This end 16 is blunt, but slightly conical, so that this end can be inserted into even the smallest incisions in the body. Further insertion is made much easier by the gradual increase in diameter.

However, the embodiment 14 according to Fig. 5 of the trocar sleeve is even easier to insert because it is completely conical and thus has no steps.

Finally, the trocar sleeve 15 can also be pin-shaped as in Fig. 6, whereby it can be extremely thin overall.

All embodiments according to Fig. 4-6 have in common that they do not have a lens or a mirror 3 at the end closest to the patient. However, this does not necessarily mean that simultaneous observation is not possible.

PATENT ATTORNEY DIPL-INQ. J. WENZEL 7 STUTTGART HAUPTMANNSREUTE 4&bgr;

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Rather, the associated endoscope can have not only a laser light guide but also an image-transmitting conductor for simultaneous observation in a known manner.

The handling during the operation with the embodiments according to Fig. 4-6 is carried out as follows:

First, the trocar sleeve with the obturator inside it is introduced into the body cavity through an incision. The bayonet lock 8, 10 is then loosened and the obturator is pulled out. Then, instead of the latter, a laser piece of the endoscope is coupled to the same bayonet lock 8, 10. The diameter of the laser piece is slightly smaller than the minimum inner diameter of the trocar sleeve on the patient-side endoscope. Then, the connecting piece 1 is connected to the gas hose for air or carbon dioxide. With a certain pressure, a quantity that depends on the pressure can be supplied to the end of the trocar sleeve near the patient. At the same time, it is possible to observe the work of the laser beam through a flexible image light guide or through a very thin periscope.

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PATENT ATTORNEY DIPL-ING. J. WENZEL 7 STUTTGART HAUPTMANNSREUTE 4&bgr;

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In addition, there is of course also the possibility of using it without simultaneous observation. In this case, an even smaller diameter is sufficient because then only a thin laser probe has to be passed through, so that in this case, for example, the trocar sleeve 15 according to Fig. 6 should be sufficient. Since in this case the play between the laser probe and the inner diameter of the trocar sleeve 15 can be even smaller, the required amount of gas can still be fed to the end closest to the patient using a somewhat higher pressure.

The invention is not limited to the embodiments shown. The person skilled in the art has the possibility of making deviations from this within the scope of the claims.

Claims (7)

JLm PATENT ATTORNEY DIPL-ING. J. WENDEL S-StutTEABT, .WAUPtMANNSREUTE 46 claims 1. Trocar sleeve for laser beam application together with an endoscope in which the device for laser beam emission is arranged, characterized in that a connection piece (1) for a gas such as air or carbon dioxide is arranged at the end of the trocar sleeve remote from the patient, that the middle region (2) of the trocar sleeve has a free passage inside, that an objective (3) with lateral beam deflection and a window (4) is arranged at the end near the patient, and that an outlet opening for the gas is provided in the region of the window. 2. Trocar sleeve according to claim 1, characterized in that the window (4) simultaneously forms the outlet opening for the gas. 3. Trocar sleeve according to claim 2, characterized in that an obturator (5) closing the outlet opening (4) can be introduced into the trocar sleeve (2). 4. Trocar sleeve according to claim 1, characterized in that the middle region (2) is mirrored on the inside. PATENT ATTORNEY DIPL-ING. J. WEIjZgL ; 7 STLjTyGfRT: ^UtfMANNSREUTE 4&bgr; 5. Trocar sleeve according to claim 1, characterized in that the end (6) of the trocar sleeve closest to the patient is blunt. 6. Trocar sleeve for laser beam application together with an endoscope in which the device for laser beam emission is arranged, characterized in that a connection piece (l) for a gas such as air or carbon dioxide is arranged at the end of the trocar sleeve remote from the patient, the middle region (2) of the trocar sleeve has a free passage on the inside and is designed to be stepped (13), conical (14) or pin-shaped (15) on the outside. 7. Trocar sleeve according to claim 6, characterized in that an obturator (5a) with a blunt end (16) near the patient can be introduced into the trocar sleeve (13, 14, 15).