DE102014010994A1 - Device for use in cryotherapy - Google Patents

Abstract

The invention relates to a device for use in cryotherapy, with an outlet opening (5), is passed through the refrigerant, in particular gas, to a point to be treated, to illuminate this point with light from an existing device on the light source (6) is. In order to realize an optimized distance setting for a user visually clearly recognizable here, it is proposed that the light source generates at least two mutually inclined light beams (12) which intersect at a predetermined distance in front of the outlet opening (4), at this point by the light beams (12) to produce a particularly intense spot of light.

Description

The invention relates to a device for use in cryotherapy, with an outlet through which refrigerant, in particular gas, is passed to a point to be treated, this point being to be illuminated with light from a light source present on the device.

Cryotherapy is the treatment of various conditions caused by the superficial action of extreme cold. As is known, this leads to various physiological effects, eg. As the reduction of the pain threshold, a reduction of spasticity, a relaxation of muscle fibers or even a hemostatic effect.

In the past, liquefied nitrogen was used in particular, but due to the special conditions under which it must be stored, it requires heavy bulky equipment. From these devices, the liquefied nitrogen constantly evaporated, causing undesirable losses. In addition, liquid nitrogen can be transported only with great effort and provide a large area, which precludes a use accordingly.

It is in this regard, for example, from the EP 0 633 998 instead of using nitrogen liquefied carbon dioxide, which is taken from a pressure bottle and passed through a pressure-resistant line to a gun-like device in which it is relaxed and then ejected. The ejected gas can reach temperatures of -75 ° C, whereby the skin treated with it can be cooled down within a few seconds from its normal temperature (about 32 ° C) to temperatures of 0 ° C to 5 ° C.

It has been found that the corresponding thermal shock z. B. leads to a neuroreflector expansion of the vessels in the affected area, which inflammatory mediators are transported away faster. Other modes of action have not yet been conclusively researched.

It is further z. B. from the DE 10 2006 037 670 known to irradiate the treated in cryotherapy treatment site of a patient with light, whereby a special depth effect with a particularly good oxygen exchange in the tissue is achieved.

In order to achieve a particularly effective effect of cryotherapy, it is necessary to observe the distance between the outlet of the refrigerant and the site to be treated as precisely as possible.

There are in the prior art the proposal to provide a kind of mechanical spacers. However, this has several disadvantages:
On the one hand, the material of this mechanical spacer, which is attached in the region of the exiting refrigerant, become brittle due to the repeated cooling in the lowest temperature ranges and is then particularly vulnerable to breakage.

Furthermore, when placing such a spacer at the Aufsetzstelle another heat transfer take place, so that there is the risk of local frostbite here. Also can be changed by the locally applied pressure from the spacer blood circulation in this area of the body to be treated, which may affect the desired effect of the refrigerant.

It is therefore an object of the present invention to develop a device as indicated above in such a way that a predetermined distance between the exit point of the refrigerant and the point to be treated can be easily maintained with it.

This object is achieved in that the light source provided in the device generates at least two mutually inclined light beams.

With a device of this type, an operator has the ability to maintain the optimum distance between the outlet of the refrigerant and the location to be treated.

The two beams of light form two spots of light at the points where they hit a body area to be treated. Now, if the point at which the two beams of light inclined towards each other intersect exactly on the surface of said body location, only a common light spot is produced by the two light beams.

By choosing the inclination of the two light beams towards each other, the position of the crossing point of the light beams can be preselected and thus the distance of this crossing point from the exit point of the refrigerant. At this predetermined distance, a user thus recognizes only one (but brighter) light spot at the location to be treated. At a smaller distance as well as at a greater distance, the light spots generated by the light beams are spaced apart so that a user recognizes two spots of light.

The thus developed device thus offers a user the ability to precisely adhere to a predetermined distance between the exit point of refrigerant and the body site to be treated, the then treated site is not touched by any mechanical spacers that could hinder the desired effects of cryotherapy.

It has been found that a very good differentiability of two light spots to a light spot and again to two light spots can be achieved if the light beams include an inclination angle of about 10 ° between them. This angle is symmetrical in particular with respect to the outlet direction of the refrigerant from the outlet opening.

In a preferred embodiment of the invention, the distance between the refrigerant outlet and the treatment site is on the order of 3 to 10 cm, preferably about 6 cm.

If the light rays are made in the same color, the two spots of light produced by them appear in the same light. Only when the two spots are superimposed do they achieve maximum brightness.

However, it is also within the scope of the invention to carry out the light beams in different colors. By then at the predetermined distance precisely superimposed light spots there then mixed the light from the two light beams and it can thus be generated a different color that makes the user observing the correct distance recognizable.

In a further embodiment of the device this is also provided with a separate distance sensor, which works for example by means of ultrasound. This distance sensor can be used to allow the escape of refrigerant from the outlet opening only from a certain minimum distance and lock again from a certain maximum distance. In this case, the intersecting light rays essentially serve to make the optimal treatment distance easier to recognize for an operator.

Regardless of the device according to the invention is also to be provided with a thermal sensor, via which the temperature of the body to be treated is to be determined.

Further advantages and features of the invention will become apparent from the following description of an embodiment. It shows

1 the perspective view of a device for use in cryotherapy

2 the sectional view of a device according to 1

3 the supervision of an assembly of the device according to 1 with light beam generating elements

In 1 a device for use in cryotherapy is shown, which has the shape of a pistol.

To a handle 1 will have a connection 2 from a (not shown) storage liquid carbon dioxide passed. By pressing a push button 3 occurs this carbon dioxide as a refrigerant at a nozzle 4 with an outlet opening and is directed to a cryotherapy to be treated site of a patient.

Laterally offset to the nozzle 4 you can see one of two light sources 6 from which the cryotherapy site to be treated is illuminated.

Furthermore, under the nozzle 4 another thermosensor 7 shown, with which the temperature of the place treated with Kryogas is determined.

In the 2 is the pistol-like grip 1 shown in broken side view. By pressing the push button 3 is via a microswitch 8th an electromagnetic valve provided in the handle 9 open and the connection 2 incoming liquid carbon dioxide is going through a pipe 10 to the nozzle 4 directed. Upon leakage of the liquid carbon dioxide from the outlet opening 5 the nozzle 4 It is relaxed and thereby goes into the gaseous state, at the same time the temperature of the carbon dioxide decreases. The gaseous carbon dioxide strikes as a substantially conical jet a site (not shown) of a patient to be treated. There, the cold carbon dioxide causes the effects of cryotherapy.

In particular, the local strong cooling effect. This is followed in the embodiment shown here via a contactless infrared measurement, including the above-mentioned thermal sensor 7 is used, which is designed in the example shown here as a thermopile sensor. At its front end, this thermopile sensor is provided with a lens, so that for this sensor at a distance between 3 and 10 cm, preferably at about 6 cm is an optimal measuring point.

For the sake of good order, it should be mentioned here that the thermopile sensor itself is integrated in a sleeve functioning as a heat sink, by which ambient temperature influences are compensated. Furthermore, the thermopile sensor is in a microchip 11 associated with a Auswertelogik in which by the refrigerant, in the present case so carbon dioxide, directly generated temperatures are hidden to determine only the actual skin temperature.

It is essential now that of the thermosensor 7 in front of the outlet 5 lying to be treated area of a patient by two light sources 6 is illuminated, which also when pressing the push button 3 from the microchip 11 to be turned on with.

With the light sources 6 can light rays 12 , z. B. from LEDs, the z. B. via lenses or light channels are generated, are generated in the 3 can be seen in a plan that is next to the nozzle 4 two light sources 6 are provided. These are inclined towards each other, so from the light sources 6 generated light rays 12 an angle 13 lock in. Due to the inclination of the two light sources whose light beams intersect 12 at a distance 14 from about 3 to 10 cm, preferably about 6 cm in front of the exit opening 5 for refrigerant of the nozzle 4 ,

In the example shown here are the light sources 6 symmetric with respect to a median plane 15 inclined by the nozzle 4 runs.

But it is also possible, depending on the structural conditions, a light source directly in said center plane 15 to arrange and then only one of the light sources 6 laterally next to this median plane 15 to place.

The light sources 6 generate light rays 12 which give a spot of light on a site to be treated on the skin of a patient. When doing the place to be treated a distance to the outlet opening 5 the nozzle 4 has, as he the distance 14 in the 3 corresponds, these two light spots from the two light sources superimpose 6 to only a brighter light spot.

This allows a user of a corresponding cryotherapy gun to realize that he has reached a predetermined, optimal for the treatment distance.

At a smaller distance, the carbon dioxide may not have been sufficiently evaporated. At a greater distance, the cold carbon dioxide gas could possibly have already mixed with warmer ambient gases and thus retain only a lower cooling capacity.

The on such a distance 14 equipped thermosensor 7 can then deliver precise measurement results, that of the evaluation logic 11 also via LEDs 16 can be signaled accordingly.

Regarding the measuring point for the thermosensor 7 is in the 2 to recognize that this is at the intersection, at which the light rays 12 to cut. This intersection lies on the center axis of the nozzle 4 exiting cryogenic gas.

LIST OF REFERENCE NUMBERS

1

grip

2

connection

3

push-button

4

jet

5

outlet opening

6

light source

7

thermal sensor

8th

microswitch

9

electromagnetic valve

10

management

11

evaluation logic

12

light rays

13

angle

14

distance

15

midplane

16

LED

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0633998 [0004]
• DE 102006037670 [0006]

Claims (4)

Device for use in cryotherapy, with an outlet ( 4 ), is directed by the refrigerant, in particular gas to a site to be treated, said point with light from an existing light source in the device ( 6 Is to be illuminated), characterized in that the light source ( 6 ) at least two mutually inclined light beams ( 12 ) generated. Device according to claim 1, characterized in that the light beams ( 12 ) at a predetermined distance ( 14 ) in front of the outlet ( 4 ). Device according to one or more of the preceding claims, characterized in that the light beams ( 12 ) have different colors. Device according to one or more of the preceding claims, characterized in that it contains a distance sensor.

Images