SURGICAL GENERATOR HAVING REMOTE-CONTROLLED FUNCTIONALITY

Abstract

A surgical generator providing a high-frequency alternating voltage to a surgical instrument. It includes a control unit and a user interface connected thereto. The control unit is configured for controlling the surgical generator based on a set of functions. A signaling interface is provided for optical signaling in a bidirectional manner to and from the remote control. The signaling interface configures the control unit and/or the surgical generator dependent on communication from the remote control. Thereby the surgical generator can be re-configured by limiting certain functions for different fields of application by the remote control. Optical signaling avoids risks of radio transmission. It is an efficient short range communication usable within same room only, providing safety against external access. Thus, re-configuration can be accomplished in a safe and cost-effective manner.

Claims

1. A surgical generator configured to output a high-frequency alternating voltage to a surgical instrument comprising a control unit and an inverter generating high-frequency alternating voltage which is output to an output socket for connection of the surgical instrument, and a user interface for user input and output being functionally connected to the control unit, the control unit being configured for controlling the surgical generator based on a set of functions, comprising a signaling interface is provided for communication of the control unit with a remote control,the signaling interface being configured for optical signaling in a bidirectional manner to and from the remote control, the signaling interface being connected to the control unit and being adapted to configure the control unit and/or the surgical generator dependent on communication received from the remote control.

2. The surgical generator of claim 1, wherein the optical signaling interface comprises two distinct channels, a first, transmitting channel for outbound communication to and a second, receiving channel for inbound communication from the remote control.

3. The surgical generator of claim 2, wherein the first, transmitting channel comprises a data field on a display of the surgical generator, the data field showing configuration data of the surgical generator fB-in a machine readable coded format.

4. The surgical generator of claim 3, wherein the second, receiving channel comprises a photosensitive sensor arranged at a housing of the surgical generator to detect external lighting conditions.

5. The surgical generator of 4, wherein the photosensitive sensor is an ambient light sensor.

6. The surgical generator of claim 4, wherein the photosensitive sensor is an infrared sensor.

7. The surgical generator of claim 4, wherein the photosensitive sensor is a camera.

8. The surgical generator of claim 4, wherein the photosensitive sensor is connected to a signal filter configured to extract a modulated signal from an output of the photosensitive sensor.

9. The surgical generator of claim 8, wherein the signal filter comprises a flicker filter.

10. The surgical generator of 8, wherein an output of the signal filter is supplied to a demodulator device of the signaling interface.

11. The surgical generator of claim 1, wherein the signaling interface is adapted to restrict the set of functions available by the control unit.

12. A system comprising the surgical generator according to claim 1 and the remote control.

13. A method of configuring the surgical generator comprising a control unit and an inverter generating high-frequency alternating voltage which is output to a surgical instrument and a user interface for user input and output being functionally connected to the control unit, the control unit being configured for controlling the surgical generator based on a set of functions, comprising optical signaling of communication data to and from an remote control via an optical signaling interface, configuring the control unit and/or the surgical generator dependent on communication data received from the remote control.

14. The method according to claim 13, comprising transmitting (-204-)-of communication data by data field (744 comprising configuration data of the surgical generator in a machine readable coded format.

15. The method according to claim 13, comprising receiving of communication data by means of a photosensitive sensor.

16. The method according to claim 13, wherein the remote control is employed for reading data in the machine-readable coded format from the data field and sending configuration data by means of a light-emitting device of the remote control, a message LED of the smart phone and/or by modulating brightness of a display of the smart phene-(9hphone.

Description

[0019] The invention is explained in more detail below with reference to an advantageous exemplary embodiment. In the figures:

[0020] FIG. 1 shows a surgical generator according to an exemplary embodiment with an attached electrosurgical instrument;

[0021] FIG. 2 shows a block diagram of the surgical generator shown in FIG. 1 and a remote control;

[0022] FIGS. 3a, b show a transmitting channel and a receiving channel, respectively, of an optical signaling interface to a remote control; and

[0023] FIG. 4 shows a flow diagram of a method according to the invention.

[0024] In the illustrated embodiment, the surgical generator is an electrosurgical generator identified as a whole by reference numeral 1. The electrosurgical generator comprises a housing 11 provided with an output socket 14 for an electrosurgical instrument 16 which, in the exemplary embodiment illustrated, is an electrocautery. It is connected via a high-voltage connecting cable 15 to the output socket 14 of the electrosurgical generator 1. A mains connecting cable 12′ connected to a plug 12, which can be connected to a public electricity grid or other suitable means of electrical supply, is provided for the supply of electrical power to the electrosurgical generator 1.

[0025] A functional block diagram of the electrosurgical generator 1 is illustrated in FIG. 2. It comprises in the housing 11a power supply unit 22 that is supplied with electrical power by the mains connecting cable 12′ (see FIG. 1). The power supply unit 22 is a high-voltage power supply unit (HVPS). It comprises a rectifier and feeds a DC link 23 with direct voltage, the DC link 23 supplying an inverter 24. The inverter 24 generates high-frequency alternating current in the high-voltage range of a few kilovolts. The high-frequency high voltage output is fed via an isolation transformer 25 to the output socket 14 via an output line 27 comprising a blocking capacitor 26. This is generally known in the art and will not be further explained for the sake of brevity.

[0026] Operation of the electrosurgical generator 1 is controlled by a control unit 10 which is connected to the power supply unit 22 and the inverter 24 by means of signaling lines 62, 63, respectively. The control unit 10 operates the electrosurgical generator 1 based on a set of functions 32 which are stored in a function memory 30. The functions 32 define operating characteristics and modes of the electrosurgical generator 1. According to an application field for the electrosurgical generator 1 at hand, certain functions may be restricted from actual use, these functions are called limited functions 31.

[0027] A user interface 4 for user input and output is connected to the control unit 10 by means of a data bus 64. The user interface 4 comprises a display 41 presenting information on the operating status or configuration of the electrosurgical generator 1 to the user and a keyboard 42 which may also be a touchscreen input device in order to enable the user to enter data and commands for the control unit 10. On the housing 11 is mounted an ambient light photosensitive sensor 81. It is configured to detect brightness of ambient light. Its output sensor signal is fed to the control unit 10 in order to determine a brightness of the display 41 of the user interface 4 dependent on ambient light conditions.

[0028] Signaling interface 5 is connected to the control unit 10 via signaling line 65. Further, the signaling interface 5 comprises two channels, a first transmitting channel 7 by virtue of which it is connected with the display 41, and a second receiving channel 8 connected to the photosensitive sensor 81 configured as an ambient light sensor. Specifically, the photosensitive sensor 81 is connected to a filter 51 which is configured to extract a modulated signal from an output signal of the photosensitive sensor 81. Thereby, a modulated signal can be extracted from the output signal of the photosensitive sensor 81, while the photosensitive sensor 81 still fulfills its main purpose of providing information about ambient light conditions to the control unit 10.

[0029] Selection of functions 31 which shall be limited from actual is not an everyday task. It is performed when setting up the electrosurgical generator 1 for its application field in which it is to be actually used, for example in a hospital. Those functions 31 that are limited shall not be presented to the user on the display 41 in order to avoid cluttering of said display and to avoid any risk of inadvertently selecting such a function. However, a restriction of the functions 31 to be limited from actual use is only to be made by an authorized user in an authorized manner, and that authorized user shall be physically present at the electrosurgical generator 1. Said user is equipped with a remote control which is typically a staple smart phone 9 running a specific app that is provided by the manufacturer of the electrosurgical generator 1. The smart phone 9 comprises a display 92, a camera 91, a flash 94 and optionally a signaling LED 93 configured to signal incoming messages to a user.

[0030] In order to configure the electrosurgical generator 1 to its application field and to select functions 32 to be restricted, the transmitting channel 7 transmits data to a data field 71 on the display 41. Thereby, said data field 71 shows visually machine-readable codes representing configuration data of the surgical generator 1 in a machine readable coded form, preferably as a QR-code 72. Thereby, a transmission channel 7 is formed, the flow of transmitted data being represented by arrow 7′ in FIG. 3a). Using the camera 91 of the smart phone 9, that visual readable machine code in the form of a QR-code 72 is read from the data field 71 and its data is conveyed to a special app running on the smart phone 9. Thereby, the smart phone 9 is enabled to accept user selections on functions 32 that are to be limited. Once the selection is made, the smart phone 9 activates a light source like a message LED 93, a background light of the display 92 or an inbuilt flash 94 such that it will emit light in a modulated manner to be received by the electrosurgical generator 1. This completes the receiving channel 8, the flow of modulated data being received is represented by square-waved line 8′ symbolizing digital data signals. Reception is to be made by the photosensitive ambient light sensor 81, and the received data will be extracted from its output signal by means of the signal filter 51 and its optional flicker filter 52 to remove signal disturbances induced by flickering ambient lighting, as it is of experienced under artificial lighting conditions. Then, the filtered signal is demodulated by a demodulator 53 and finally supplied to the signaling interface 5. This interface then transmits the data to the control unit 10, thereby effecting a configuration concerning the limited functions 32 as selected by the user on his smartphone 9.

[0031] Rather than the ambient light sensor 81 as a photosensitive sensor, also a special light sensor 82 may be used that is configured as a sensor for receiving optical signals. Further, it is also possible to employ a camera 83 to receive said optical signal, thereby enabling also an optional direct reading from the display 92 of the smart phone 9. Such a camera 83 is particularly useful for reading of more complex machine-readable codes shown on the display of the smartphone 9. Examples for such more complex machine-readable code are moving graphic codes like so called “flicker codes” (known in the banking field for controlling TAN generators), allowing a rather high speed of data transmission and/or usage of codes having higher redundancy for safety and security.

[0032] As all these are optical means of transmission and reception, issues with radio and radio interference are completely avoided. Further, since such optical signals do not travel through walls or doors, there is implicit safety by requiring physical presence of the person authorized to perform the configuration in the same room. Therefore, physical presence is required thereby achieving a similar or better degree of safety compared to a conventional configuration interface being nested in a menu structure of the electrosurgical generator.

[0033] The steps of the method to be performed in order to configure the electrosurgical generator 1 accordingly are shown in FIG. 4. In the first step 101, the configuration process is initiated on the electrosurgical generator 1. Then, the control unit 10 via the optical signaling interface 5 displays a data field 71 comprising visually machine-readable code, like said QR-code 72, in step 103. This establishes transmitting 204 of the optical signal via the transmission channel 7 to the smart phone 9. In a next step 903, said visual machine-readable code is read by the camera 91 of the smart phone 9. Processing and selection of appropriate function is performed on the smart phone in step 904. When completed, configuration data is then emitted from the smart phone 9 in step 905, e.g. by flashing a background light of the display 92, a messaging LED 93 or the flash 94 of the smart phone 9. The modulated data sent thereby via the receiving channel 8 is received in step 206 and read by the photosensitive sensor 81 in step 107 with subsequent demodulation. This data is then processed by the optical signaling interface 5 and outputted in step 109 to the control unit 10 in order to limit certain functions 31, thereby configuring the surgical generator 1.