INSUFFLATION DEVICE AND OPERATING METHOD THAT CAN BE CARRIED OUT THEREWITH

Abstract

The present invention relates to an insufflator with integrated flue gas extraction. Thanks to a novel valve regulation system, it is possible to direct the gas inflow through two tubes into the body cavity. The novel device also enables an improved pressure control of the body cavity, which leads to lower pressure variations in the body cavity and furthermore compensates higher leakage volume flows.

Claims

1.-5. (canceled)

6. A medical assembly for use in minimally invasive surgery, comprising: (i) an insufflator which includes: a gas supply line for receiving a gas supply; a first pressure and flow control unit equipped with a proportional valve and a pressure sensor, the first unit adapted and configured to receive at least a portion of the gas supply from the gas supply line; a second pressure and flow control unit equipped with a second proportional valve and a second pressure sensor, the second unit adapted and configured to receive at least a second portion of the gas supply from the gas supply line; an in-feed line with filter operatively connected to the first pressure and flow control unit; an extraction line with filter operatively connected to the second pressure and flow control unit and an extraction device; a secondary gas supply line extending between the gas supply line and the second pressure and flow control unit, and an electronic control unit; (ii) a first trocar connected to a distal end of the in-feed line, and (iii) a second trocar connected to a distal end of the extraction line.

7. The medical assembly as recited in claim 6, wherein the insufflator further includes a shut-off valve operatively arranged between the extraction device and the extraction line.

8. The medical assembly as recited in claim 6, wherein the extraction device is part of the insufflator.

9. The medical assembly as recited in claim 8, wherein the extraction device has variable extraction power.

10. The medical assembly as recited in claim 6, wherein the filter associated with the extraction line includes a flue gas filter and a separate supply gas filter.

11. A filter for use with an insufflator according to claim 6, comprising: a filter housing for connection to the insufflator housing, wherein two gas conduits extend from the insufflator housing into the filter housing, one gas conduit being an extraction conduit and the other being a gas supply conduit, at least one flue gas filter associated with the extraction conduit and optionally a second supply gas filter associated with the gas supply conduit, wherein both conduits extend to a common outlet of the filter housing, which is connected to the second trocar.

12. A method for pressure measurement in a patient cavity during insufflation using the medical assembly according to claim 7, comprising the steps of: closing the proportional valve in the first pressure and flow control unit; opening the second proportional valve in the second pressure and flow control unit; closing the shut-off valve; supplying insufflating gas to the patient using the second pressure and flow control unit via the second trocar; and measuring a patent cavity pressure using the pressure sensor associated with the first pressure and flow control unit while the insufflating gas is being supplied to the patient via the second trocar.

13. A method for providing insufflation gas to a patient using the medical assembly according to claim 6, comprising the steps of: closing the shut-off valve; opening the second proportional valve in the second pressure and flow control unit so that a second portion of the gas supply from the gas supply line is provided to the extraction line and to the second trocar.

14. The method according to claim 13, wherein a maximum gas volume flow from the insufflator to the patient is approximately doubled when the gas is supplied via both the first and second trocars in comparison to when the gas is only supplied via the first trocar.

Description

IMPROVED PRESSURE MEASUREMENT METHOD

[0013] The insufflator according to the invention also enables an improved pressure control and measurement during the insufflation. In the conventional insufflators, the pressure measurement for measuring the pressure in the body cavity is performed by a sensor that is located at the insufflator-side end of the tube in the pressure and flow control unit. In order to be able to measure the pressure in the body cavity, the insufflation is interrupted for several hundred milliseconds. During this time, a pressure equalization between the body cavity and the tube content is obtained, which then can be measured. Thereby, the pressure in the body cavity can be determined sufficiently precisely, without having to use a pressure sensor in the body cavity. After completion of the pressure measurement, the insufflation is continued. In this way, a pulsatile gas supply occurs, with measurement phases alternating with insufflation phases. This change is not critical for body cavities of normal sizes (e.g., abdomen). For smaller body cavities, such as the rectum, this mode of operation will lead, however, to induced pressure variations in the body cavity.

[0014] The insufflator according to the invention permits an improved mode of operation: In the insufflator according to the invention, too, the gas supply in the in-feed line is interrupted for the time of the pressure measurement. Simultaneously with the interruption, the gas supply is passed through the second line. This kind of gas supply permits an undisturbed measurement of the pressure in the cavity by the first pressure sensor, with simultaneous continuation of the gas in-flow.

[0015] The device according to the invention is illustrated in FIG. 1. To begin with, the gas supply (1) is shown (e.g., a CO.sub.2 bottle). The gas supply line (2) leads inside of the insufflator to a first pressure and flow control unit (3). In the pressure and flow unit, there are a proportional valve, a pressure sensor, and a flow sensor. The line (4) extends to a filter (5) at the outlet of the housing. By means of a tube (6), a trocar (7) is connected. This trocar (7) conducts the gas flow into the cavity of the patient. In the cavity of the patient, there is provided a second trocar (8). By this second trocar (8), as a rule, a gas extraction is performed. For this purpose, the trocar is connected by means of a tube (9) to another filter (10). The line (11) leads via an optional shut-off valve (13) to the extraction pump (14) and from there via a line (15) to an outlet (16) for the extracted flue gas. Between the filter (10) and the shut-off valve (13), a second pressure and flow control unit (18) is positioned by means of a T piece (17). The second pressure and flow unit is also connected via a line (19) to the gas connection (1).

[0016] Via this second line (9), insufflation gas can be supplied to the second trocar (8). The shut-off valve (13) must be closed, when the parallel insufflation via the second trocar (8) is to be performed. It goes without the shut-off valve, when the extraction pump has a sufficient resistance or inertia, and the pressure cannot be reduced via the pump. By this parallel insufflation via both trocars (7 and 8), a practically twice as high insufflation volume flow as with one line only can be obtained. This parallel insufflation permits maintaining a sufficient pressure in the patient in special cases, e.g., larger leakages. The electronic control unit is not shown in FIG. 1.

[0017] In practical operation, the filter (10) is contaminated with the flue gas emissions. In order to prevent that particles, and in particular germs, find their way back into the abdomen of a patient, when using the second insufflation path from the filter (10) via the trocar (8), there is of course the possibility to connect the line of the second pressure and flow control unit (18) behind the filter (10) only to the line to the trocar (8). For this purpose, a corresponding filter housing (23) is designed, which simultaneously enables the filtration of the flue gases via a filter (20), but also permits the connection of the gas flow of the second pressure and flow control unit (18) via a filter (21) to the trocar (8). Such a solution is shown, for example, in FIG. 2.

[0018] The insufflation unit according to the invention also permits an improved pressure measurement in regular operation. As explained above, for the purpose of the pressure measurement, the valve at the pressure sensor in the pressure and flow unit (3) is closed for several hundred milliseconds. After pressure equalization between the cavity of the patient and the line system, the pressure is detected by the pressure sensor. After pressure measurement, the proportional valve in the pressure and flow unit (3) is re-opened, and the insufflation is continued. During the pressure measurement, there is no further insufflation possible in the conventional insufflators. The insufflator according to the invention enables a continuous insufflation by the following method of operation:

[0019] For the purpose of the pressure measurement, the proportional valve in the first pressure and flow control unit (3) is closed. At the same time, the valve in the second pressure and flow control unit (18) is opened, so that the insufflation is performed for several hundred milliseconds with the same insufflation power via the trocar (8). When a flue gas extraction occurs, the shut-off valve (13) can be closed for the time of the pressure measurement. After completed pressure measurement, the proportional valve in the second pressure and flow control unit (18) is re-closed, and the proportional valve in the first pressure and flow control unit (3) is re-opened. If necessary, the control valve (13) is also re-opened, so that a flue gas extraction is possible. The advantage of this method of operation is that a continuous insufflation is obtained, and thus the pressure in the cavity varies significantly less than with conventional methods.