The present invention relates to surgical devices and, more particularly, to a surgical device that includes an impact detector for detecting the occurrence of impacts suffered by the surgical device. The invention further relates to a polling device for polling information concerning the occurrence of an impact from the surgical device and to a navigation system comprising the polling device.
Surgical devices, such as, for example, instruments, implants or marker means for surgical navigation systems, should have reliable geometric properties, e.g., the devices should be dimensionally stable. An impact, for example due to the surgical device falling on the floor, however, can alter the shape of the surgical device. If a surgical device has suffered an impact, this also can be an indication that the surgical device has become non-sterile and/or has an altered shape, which means that the surgical device can no longer be safely used for surgery.
A surgical device in accordance with the invention is configured to provide information that can be used to detect a change in shape (e.g., an undesirable change in shape) in the surgical device. Such change in shape may increase a risk of navigation error, for example, if the damaged device were used in navigated surgery. Examples of such surgical devices include a knife, a biopsy needle, an injection apparatus comprising an injection tip, a drill, etc. The surgical device also can be an implant, such as for example an artificial hip joint, or it can be a trackable marker device (e.g., a reference array) used with surgical navigation systems. In such marker systems, a defined relative position between marker elements (e.g., marker spheres) of the marker device is important, and this relative position can be altered by an impact. Examples of marker devices include reference stars in which marker spheres assume a predetermined position relative to each other due to rigid connecting members. The impact detector can be used to monitor the dimensional stability of the surgical device and/or to determine the risk of a change in shape.
The surgical device can comprise a transponder, e.g., an RFID transponder, microchip transponder, a card transponder or a radio transponder, in which the geometric properties of the surgical device may be communicated to or stored thereon, wherein the geometric properties describe a shape of the surgical device. In the following, the RFID transponder is cited by way of example.
The geometric properties (geometric data) are preferably stored together with the date the geometric properties were measured. If the impact detector of the surgical device indicates an impact of an appropriate intensity (particularly if the impact occurred after the surgical device was calibrated or surveyed), then the geometric properties stored on the transponder are regarded as being invalid.
The impact detector, which can be configured as a passive detector (i.e., the detector has no power supply of its own) serves to detect the occurrence of an impact, wherein the impact detector can alter its state as a result of an impact (e.g., an impact that exceeds a particular threshold). This state represents one example of impact occurrence information that can be retrieved from the transducer.
The impact detector also be designed as an active detector (i.e., the detector has its own power supply) and can comprise an acceleration sensor (also called a crash sensor, shock sensor or impact sensor). The acceleration sensor can provide acceleration data metered over time, which for example can be captured by a microchip or microprocessor and (electrically) stored as data. These sensors also can capture an average value or maximum value of acceleration and emit corresponding signals and/or data. The acceleration data represent examples of impact occurrence information.
The impact sensor of the impact detector is preferably designed such that the action of an impact alters an electrical property of the sensor, which then can be polled to detect the impact. In a particular embodiment, the electrical and/or mechanical property of the impact sensor is permanently altered if the intensity of the impact exceeds a predetermined threshold. The impact sensor, for example, can be configured such that a wire breaks if the intensity of the impact exceeds the predetermined threshold. The break in the wire can cause a significant change in the electrical properties of the sensor (significant increase in resistance and/or high-frequency resonance properties). The electrical property represents an example of impact occurrence information.
The altered resistance, for example, then can be polled by an electric circuit. Alternatively, the altered high-frequency resonance property, which represents the impact occurrence information, can be detected by means of high-frequency waves, similar to or in accordance with a transponder. The impact detector preferably comprises a transponder or is coupled to a transponder such that the altered electrical and/or mechanical properties of the impact sensor are transmitted to the transponder or alter information that can be polled by transponders.
The surgical device is preferably designed such that the impact detector can be removed and/or exchanged and/or reset to its original state (e.g., the state prior to impact). This is particularly advantageous when the impact detector permanently alters its (electrical) state due to a (sufficiently intense) impact, wherein an impact is to be regarded as any type of occurrence that is a mechanical burden that may damage or even destroy the surgical device. Maintenance then can be performed on the surgical device such that the impact detector can be made “active” again by replacing or resetting the sensor or sensor element (e.g., analogous to replacing a fuse or resetting a circuit breaker in an electrical circuit). During maintenance, the geometric properties of the surgical device can be resurveyed (i.e., the surgical device can be recalibrated). The newly measured data, for example, then can be stored in a transponder, in particular an RFID transponder, situated within the surgical device. In this respect, reference is also made to European patent application No. 06 019 346.3 (U.S. patent application No. 60/826,973), which describes a measuring device for measuring geometric properties of a medical treatment device, wherein an RFID writer writes the geometric properties (geometric data) of the medical treatment device in an RFID transponder situated in the medical treatment device. The apparatus recalibrated in this way and comprising a replaced or re-activated impact detector then can be used again. The surgical device in accordance with the present invention can comprise the features of the medical treatment device of European patent application No. 06 019 346.3 or U.S. patent application No. 60/826,973, the contents of which are hereby incorporated by reference in their entireties.
As stated above, the impact detector can be directly polled, in particular electrically, by a polling apparatus. To this end, electrodes, for example, can be provided on the surgical device, and a polling apparatus can be connected to these electrodes so as to enable measurement of the resistance or capacitance of the impact detector. Preferably, however, polling is contact-free via an electrical alternating field, for example, in particular a high-frequency field that detects an altered resonance frequency of the impact detector.
In accordance with another embodiment, the surgical device comprises a transponder, in particular an RFID transponder, which for example can (but need not) store geometric data concerning the surgical device. The transponder can be used to store the information ascertained by an impact detector concerning the occurrence of an impact and/or to transmit the information to a transponder reader, such as an RFID reader. To this end, the transponder is preferably electrically coupled to the impact detector. The impact detector, for example, can transmit data to the transponder, or the transponder can poll said data from the impact detector, wherein the data reflects the occurrence of an impact. These data then can be stored in memory by the transponder and retrieved therefrom as necessary by a transponder reader.
Even if the impact detector is designed as a passive detector, the value of a memory cell, in particular the binary value, can be altered, for example by altering a resistance value of the impact detector if an impact is sufficiently intense. The altered memory contents of the memory cell are then in turn read by a transponder reader, such as an RFID reader, making it possible to determine whether or not the surgical device has been exposed to an impact.
A polling device in accordance with the invention is designed to poll the surgical device to read impact occurrence information and/or geometric data stored in a transponder, such as an RFID transponder, wherein the geometric data represent the geometric properties of the surgical device. The polling device preferably also comprises a comparing unit which compares impact tolerance information with the polled impact occurrence information. The impact occurrence information, for example, represents acceleration data recorded by the impact detector or reflects the state of the impact detector (e.g., if it is designed as a binary detector that only conveys whether or not an impact has occurred). The polled impact occurrence information is preferably compared by the comparing unit with impact tolerance information. This applies in particular when the impact occurrence information includes information concerning the intensity of the impact and/or acceleration that the surgical device has suffered. Such impact occurrence information can be compared with impact tolerance information in order to determine whether the intensity of the impact was above a threshold. If the intensity of the impact was above the threshold, then a risk of damage to the surgical device or of a change in the shape of the surgical device can be assumed. In particular, it may be assumed that the geometric data, which in one embodiment are additionally output from the transponder (e.g., via an RFID transponder) of the surgical device, are no longer reliable.
The polling device is preferably configured such that, in addition to the impact occurrence information, also reads identification data from the surgical device. The identification data, for example, can be stored in a transponder, in particular an RFID transponder, provided in the surgical device. On the basis of the identification data read from the surgical device, a database can then be polled in which different impact tolerance information is respectively assigned to the identification data. The impact tolerance information, for example, represents the intensity of an impact value at which the risk of a change in shape is not yet to be anticipated or beyond which such a risk is to be anticipated. The impact tolerance information is preferably assigned to the individual types of surgical devices by means of the identification data. Different types of surgical devices can have different impact tolerances. In this way, it is then possible to individually determine, depending on the type of surgical device, whether or not there is a risk of deformation. The polling device preferably comprises the aforesaid database. The polling device preferably comprises a warning unit that warns a user if the result of the comparison made by the comparing unit indicates a risk of deformation, e.g., indicates that a tolerance has been exceeded. In particular if the transponder additionally stores the geometric data of the surgical device, it is possible, if there is such a risk, to block the geometric data from being read from or relayed, or to only enable the geometric data to be relayed in combination with a warning indication.
A system in accordance with the present invention can include the aforementioned surgical device, polling device, and/or a navigation system, in particular for performing IGS (image-guided surgery). Preferably, the polling device is included in the navigation system. If the polling device determines that a tolerance has been exceeded or that there is a risk of deformation, the navigation system preferably outputs a warning signal and/or blocks navigation of the surgical device for which a risk of deformation has been determined. In this way, it is possible to prevent deformed surgical devices from being used in medical surgery. In particular, it is possible to prevent geometric data of the surgical devices which are no longer valid due to an impact, but which are still stored in a transponder of the surgical device and are read by the polling device of the navigation system, from being assigned by the navigation system. This avoids faulty or risky geometric data being used in navigating the surgical device. In particular, it can cause the geometric properties of the surgical device to be newly surveyed and stored in the transponder, in particular an RFID transponder, before the surgical device is used again.
The forgoing and other features of the invention are hereinafter discussed with reference to the drawing.
a and 2b schematically show an exemplary non-reusable impact sensor that can be used with the surgical device of
The transponder chip 14 is coupled to antenna 16 for receiving and transmitting signals (e.g., the transponder can output signals to the antenna 16 for wireless transmission of the signals). The antenna 16 interacts with a high-frequency electromagnetic alternating field emitted by an antenna 26 of a transponder reader, in particular an RFID reader 20. Using this interaction, signals can be transmitted to the instrument 10, more specifically to the transponder chip 14, and signals from the transponder chip 14 can be received by the transponder reader, in particular the RFID reader 20. The transponder reader, for example, can relay the received data to a navigation system 28 or can be part of such a navigation system. The transponder reader 20 represents an example of a polling device in accordance with the invention.
The polling device 20 may include a memory 22 for storing data therein. This data can include, for example, identification information of the surgical device 10 (e.g., a code that identifies a characteristic of the device or identifies the device itself), tolerance data (e.g., maximum impact data), etc. that may be used by the polling device 20 (or other device) to determine if the surgical device 10 has undergone an impact exceeding a predetermined threshold. The polling device 20 also includes a comparator unit 24, wherein the comparator unit receives impact information from the surgical device 10 via antenna 16 and antenna 26, as well as tolerance information from memory 22. By comparing the tolerance information and the impact information, a determination can be made whether or not the surgical device 10 has undergone an impact that exceeds a predetermined threshold. If the device has undergone an impact that exceeds the predetermined threshold, then this information can be communicated via warning unit 27, which is operatively coupled to the comparator unit 26.
The sensor 12, for example, can be an impact sensor or an accelerometer. Examples of impact sensors and their applications are for example described in the following documents, the contents of which are hereby incorporated by reference in their entirety.
a and 2b show the principle of operation of a non-reusable impact sensor 12. An inert mass part 100 is connected to an electrode 120 via a spring 110. In
The impact sensor in accordance with
Although the invention has been shown and described with respect to a certain preferred embodiment or embodiments, it is obvious that equivalent alterations and modifications will occur to others skilled in the art upon the reading and understanding of this specification and the annexed drawings. In particular regard to the various functions performed by the above described elements (components, assemblies, devices, compositions, etc.), the terms (including a reference to a “means”) used to describe such elements are intended to correspond, unless otherwise indicated, to any element which performs the specified function of the described element (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary embodiment or embodiments of the invention. In addition, while a particular feature of the invention may have been described above with respect to only one or more of several illustrated embodiments, such feature may be combined with one or more other features of the other embodiments, as may be desired and advantageous for any given or particular application.
Number | Date | Country | Kind |
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07102641.3 | Feb 2007 | EP | regional |
This application claims priority of U.S. Provisional Application No. 60/893,242 filed on Mar. 6, 2007, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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60893242 | Mar 2007 | US |