SE469318B - DEVICE FOR HEAT TREATMENT OF PROSTATA - Google Patents

Description

-r 469 me: 2 the surroundings. Through the small dimensions of the sensor you achieve even a small time constant, of the order of 1 second, which enables rapid detection of changes in temperature, which increases the safety of temperature monitoring. By materials without electrical conductivity utilized are eliminated also the risk of electric shocks.

A device of this kind is described in EP, A1, 0 370 890 and WO, A1, 91/13650. In this case, the temperature sensor can be arranged inside the catheter itself.

A significant disadvantage of the known devices of this kind is that the unit cost is relatively high and because the fiber The optical sensors are firmly integrated in the catheter and they can be probed is not heat sterilized without damaging the sensors current temperature range. In practice, this means that the device will only be used once with a lot high instrument cost per procedure as a result.

The object of the present invention is to remedy the above discussed the shortcomings of prior art constructions and provide a new device for heat treatment of the prostate at which the temperature sensor is integrated with the catheter and gives an accurate and reliable measurement result.

This is achieved with a device of the type initially indicated with the features specified in claim 1.

Because the temperature sensor is arranged detachable from The catheter achieves two essential benefits. Namely, partly, which is the most important advantage from a cost point of view, that the catheter can be heat sterilized separately without the risk of it optical fiber temperature sensor should be damaged, partly that the sensor can be detached to be checked independently of the catheter and possibly calibrated.

Experiments have shown that the catheter, when it consists of silicone rubber, can be autoclaved at a temperature of about 135 ° C about 25 times. This means that the device cost of one intervention is only about 4% of what the corresponding cost is for a procedure according to the prior art.

Another significant advantage of the device according to The finding lies in the fact that it is designed to utilize the light frequency for the temperature determination, since frequency signals is normally of higher quality than amplitude signals, and thus gives 3 i 469 318 more reliable temperature measurement.

According to an advantageous embodiment of the device according to the invention is the catheter made of silicone rubber, which is a substance which allows autoclave sterilization of the catheter at a _ temperature of 135 ° C and thus the use of catheter one several times, which is of great economic importance when the position of the catheter is relatively costly.

According to another advantageous further development of the device according to the invention, alarms are set up to stop energy supply to the microwave applicator if the temperature is intraurethral or maximum measurement temperature rectally exceeds established limit values. The limit value for the temperature intraurethral can be 45 ° C, with the temperature a few mm outside the catheter, inside prostate, amounts to 50-55 ° C, and in the rectum, appropriate value be 42-45 ° C.

The invention will now be described in more detail with reference to the accompanying drawings in which Figure 1 shows a schematic dovy of an embodiment of the catheter of the device according to the figure, Figure 2 shows on an enlarged scale a cross-section of Figure 3 shows in side view a practical embodiment of the catheter. Figure 4 shows an embodiment of the rectal probe.

Figure 1 shows a urethral catheter 2 intended to be inserted into the urethra of the patient to be treated.

Inside the catheter 2 there is a microwave applicator 4, or tin, which is fed through a cable 6 from a microwave source.

The antenna or applicator 4 is a dipole antenna. A problem in this context, the antenna cannot be fed normally method with a perpendicularly extending supply cable, as such of the dipole antenna and the supply cable formed T-configuration can not inserted into the catheter. The supply cable must thus run in parallel with the dipole antenna, whereby the cable will interfere with the antenna.

In a practical embodiment, one part of the dipole consists of one coaxial cable, which is peeled at the end so that the inner conductor protrudes out, and the supply cable forms the other part of the dipole. In order to eliminate reduce the problem of earth currents, which arise in such an tin, a ferrite ring is arranged around the supply cable, which gives one strong inductance in the shield of the supply cable and thus generates one interruption in this.

The location of the catheter 2 in the urethra and thus the micro- 46 .f 318: the wave applicator 4 is made by means of an expandable cuff 8, which O / 4 after insertion into the bladder is expanded by pumping the saline through the conduit 10, whereupon the cuff 8 thus forms a position reference for catheter 2 and thus microwave applicator 4 at its position towards the bladder bottom. In this case, it is ensured that microwave The equator 4 ends up in the area of the prostatic urethra, where the the treatment must take place.

Figure 3 illustrates the extent of the heat treatment area, with heat maximum lying a few mm outside catheter 2, at 9.

The length of the heat treatment area along the catheter is typically to 35 mm and it reaches out about 15 mm radially from the catheter side.

For intraurethral temperature monitoring, a temperature temperature sensor device arranged in the form of a glass fiber 12 2 mantle made channel 14. At the measuring end an aluminum-gallium-arsenide stack 16, carried in one on the catheter of the fiberglass 12 is available which, when excited by light through photoluminescence, emits light the wavelength or frequency is strong temperature dependent in a reproducible manner. Photoluminescent the light is returned by the fiber 12 without being affected by the sending the light to a measuring unit 18, containing optical and semiconductor detectors, which via algorithms in a computer on the other hand, measures the intensity of the light to check that the direct function, and measures the wavelength of the light for temperature other wavelength, whereby atmosphere. The fiber is surrounded by a protective sheath with an outer diameter of 25 mm. The fiber 12 is connected to the measuring unit 18 with an optical contact 30. The measuring unit 18 emits semiconductor generated red light, by means of LED, as of fiber 12 led to the sensor end, where the aluminum-gallium-arsenide stack 16 is provided. The stack is made with extremely small dimensions. and enclosed in an acrylate shell to the same outer surface. diameter as the fiberglass casing.

The catheter 2 is also made with channels for coolant. Inlet The coolant 20 is connected to the channels 24 inside the catheter and coolant are returned to the outlet 22 through the space 26. Between the outer wall of the catheter 2 and the septum between the mean 24 and 26 there are transverse partitions 28, which serve as a spacer, see Figure 2. As coolant, ordinary tap water can be used. To reduce the overpressure relative to the patient in the cooling water channels 24, 26 the cooling water is pumped in through the inlet 5 46? 318 20 under pressure and simultaneously sucked out at the outlet 22. A condition countrywise small amount of coolant of the size 1-2 dl circulates in cooling system at a rate of 4-7 ml / s. You use a pre- relatively small amount of coolant for safety reasons. If an error would occur so that the coolant is pumped into the bladder is present then there is no risk of it cracking when using these flames cooling water volumes.

The fiber 12 of the temperature sensor device is inserted into a on the outside of the catheter 2 which is likewise made of silicone rubber. mi. The fiber can be pushed into a stop (not shown) at which the measuring stack 16 is located approximately in the middle of the microwave application. torn 14.

The measuring fiber 12 is extendable from the channel 14, whereupon the entire catheter is otherwise sterilizable by autoclaving at a temperature 135 ° C. The temperature sensor with its fiber is calibrated appropriately between each treatment and the device according to the invention may advantageously be equipped with a calibration furnace where the The ringing is done automatically with high precision.

The temperature sensor can also be affected by the proximity to the low temperature fluid flow in catheter 2, i.e. there is a risk that the intra-urethral sensor indicates a lower temperature than the actual temperature, which error display then becomes dependent of the coolant temperature. With one in the device according to the invention incoming computer, a compensation is made every second calibration, so that this error display is eliminated, regardless of refrigerant temperature.

This compensation is performed so that the temperature is measured in one thermostated water bath where the temperature of the flowing the water can be controlled very precisely. With an intra-urethral probe of the type included in the device according to the invention, the the temperature response in such a test setup from the fiber sensor, with connected cooling water flow of different temperature. Here can be how the compensation value is affected by different refrigerants temperature within the current range 20-5 ° C.

Practical tests have also shown the disturbance from the refrigerant slightly reduced with the probe against wet skin compared to dry skin. Even when no power is applied, some cooling takes place through cooling. the fluid of both the probe and surrounding tissue. A certain small minimum power may therefore be suitable to add during heating ._ _ 469 318 '6 in "zero position".

The temperature and temperature profile as in the heat treatment achieved at the rectal mucosa is monitored by three sensors 32, 34, 36 arranged on the probe 38, intended to be inserted into the rectum, see Fig. 4.

The temperature sensor devices at the rectal probe 38 are similar to designed as the urethral temperature sensor device with glass fibers 40,42,44, arranged along the outside of the probe body. They off the measured temperatures of the rectal temperature sensors are read once per second and it is verified in the measuring equipment that it the highest sensor temperature is below the set alarm limit. If if this limit is exceeded, the energy supply to the microwave the applicator. The glass fibers, like the urethral glass fiber, are arranged in surface-mounted channels or hoses of silicone rubber in which they have been pushed to calibrated stop positions. The channels or the tubes are mounted in a longitudinal groove in the probe body the patient's forward-facing exterior. The rectal probe is also completely made of silicone rubber and can be reused several times. The probe has been given a good one anatomical shape and is provided with rotation protection. torsional protection is important, as a twisting of the probe causes sores 32, 24, 36 end up anatomically wrong in the patient.

The cooling water is cooled in a cooling system consisting of heat exchangers with associated cooling system, cooling regulator and circulation pump.

The cooling system includes a so-called Peltier system with a large amount of Peltier transitions. The Peltier system has the ability to very quickly change the temperature of the coolant. * s

Claims (9)

\ l - [11 ON \ O (Al --Å | OO Patent claim A device for heat treatment of the prostate, comprising a single-cooled urethral catheter (2), in which a microwave applicator (4) is arranged to heat an area around the prostatic urethra, the catheter (2) being associated with a temperature sensor, which comprises an optical conductive fiber (12) with a luminescent element (16) arranged at its measuring end, which emits a light dependent on its temperature, the measuring end in use being located in the catheter (2) in the heat treatment area, characterized in that the outside of the catheter (2) consists of a sterilizable material and that the temperature sensor is detachably integrated in the catheter (2). Device according to Claim 1, characterized in that the optically conductive fiber (12) is extensively arranged in a longitudinal channel (14) arranged in the jacket of the catheter (2). Device according to claim 1 or 2, characterized in that the catheter (2) is made of an autoclavable material. Device according to claim 3, characterized in that the catheter (2) is made of silicone rubber. Device according to one of Claims 1 to 4, characterized in that an alarm is arranged to stop the energy supply to the microwave applicator (4) if the temperature detected by the temperature sensor uretrically exceeds a predetermined, first limit value. Device according to claims 1-5, characterized in that the luminescent element is an aluminum-gallium-arsenide stack (16) arranged to emit light of a temperature-dependent frequency when it is light-charged. Device according to one of Claims 1 to 6, characterized in that a measuring unit (18) is connected to the optically conductive fiber (12), which measuring unit (18) comprises an optical filter and semiconductor detectors for measuring, on the one hand, the intensity of the luminescent light to check the fault-free function of the fiber, as well as the frequency of the light for temperature determination. Device according to one of Claims 1 to 7, characterized in that the rectal probe comprises a plurality of temperature sensors, arranged to give a heat profile rectally. Device according to claim 8, characterized in that an n.- 469 518: 8 alarm is arranged to stop the energy supply to the microwave applicator if the highest temperature, rectally detected by the temperature sensors, exceeds a predetermined, second limit value.