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Medical probes with field transducers

a technology of field transducers and medical probes, which is applied in the field of medical probes with field transducers, can solve the problems of different patients, impracticality of stock transducer-equipped probes in all different configurations, and considerable trauma, and achieve the effect of sufficient accuracy

Inactive Publication Date: 2002-03-14
BIOSENSE
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0009] Because the transform between disposition of the first field transducer and disposition of the probe body feature is determined during the calibration cycle, there is no need for any particular, predetermined spatial relationship between the first field transducer or position sensor and the distal end or other feature of the probe body to be tracked by the system during use. All that is required is that the spatial relationship remain fixed after calibration. Thus, according to this aspect of the invention, there is no need for any special configuration of the probe body; provided that the first field transducer or position sensor can be securely attached to a medical instrument of any type which can be inserted into the patient or contacted with the patient, that medical instrument can serve as an instrumented probe. This aspect of the invention allows the physician to use existing tools and to track the disposition of existing tools in the same manner as a specialized sensor-equipped probe.
[0013] The calibration steps can be repeated several times for a single feature of the probe body, using the same or different known dispositions and calibration dispositions, so as to enhance the accuracy of the calibration process. Alternatively or additionally, the calibration steps can be performed using more than one feature of a probe, so that a separate transform is developed for each feature. During use, the system can track all of the features for which such calibration steps were performed. For example, where a probe is bent to a user-defined shape, the calibration step can be performed for many points along the probe, and the system can display locations of these many points during use. Thus, the system can display a realistic depiction of the user-defined shape. A disposable device according to a further aspect of the invention includes a field transducer as discussed above, and a mounting element for securing the field transducer to a medical instrument, the mounting element being adapted to engage a body of the medical instrument so that said disposable device cannot be removed readily from the instrument without altering at least one feature of the disposable device. For example, the mounting element may be adapted to engage the instrument so that said device cannot be removed readily from the instrument without deforming or breaking a part of the mounting element. Devices according to related aspects of the invention incorporate the field transducer, a mounting element and a usage monitoring circuit element for recording use of the device. Thus, the usage monitoring circuit element may provide an indication representing the number of times the disposable device has been used or the total time the disposable device has been operatively used. These arrangements help to prevent improper reuse of the device.

Problems solved by technology

Because these procedures create considerable trauma to the patient, physicians have developed minimally invasive procedures using probes inserted into the body.
However, this option is available only for probes such as conventional endoscopes which are large enough to accommodate the optical elements.
It is impractical to stock transducer-equipped probes in all of the various configurations required to accommodate different patients.

Method used

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  • Medical probes with field transducers
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  • Medical probes with field transducers

Examples

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Embodiment Construction

[0028] A disposable device in accordance with one embodiment of the invention includes a field transducer 30 permanently mounted in a body 32. Field transducer 30 is adapted to detect or radiate a non-ionizing field such as a magnetic, electromagnetic or acoustic field in such a manner that disposition of the field transducer can be at least partially determined from properties of the detected or radiated field. Field transducer or sensor 30 may be a multiaxis, solid-state position sensor of the type disclosed in U.S. Pat. No. 5,558,091. Such a multiaxis sensor includes a plurality of transducers sensitive to magnetic field components in mutually orthogonal directions. Other suitable field transducers or sensors include coils as disclosed in the aforementioned U.S. Pat. No. 5,391,199 and PCT International Publication WO 95 / 05768, incorporated by reference herein. The coils may be provided as a single coil having a single axis of sensitivity or as a plurality of mutually orthogonal c...

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PUM

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Abstract

A field transducer (30) for determining position or orientation in a medical instrument locating system is placed at an arbitrary position or orientation with respect to a feature (62) of the instrument (46). The transducer (30) may be attached at an arbitrary location on the instrument (46), or the instrument (400, 404) may be bent as desired by the user. A transform relating position or orientation of a feature of the instrument to position or orientation of the transducer is obtained in a calibration cycle. A field transducer may be part of a disposable unit which is irrevocably altered when used with an instrument, so that the unit cannot be reused.

Description

[0001] The present invention relates to medical probes having field transducers used for detecting the disposition of the probe, and to the medical procedures utilizing such probes.[0002] Conventional surgical procedures involve cutting through bodily structures to expose a lesion or organ within the body for treatment. Because these procedures create considerable trauma to the patient, physicians have developed minimally invasive procedures using probes inserted into the body. For example, devices commonly referred to as endoscopes include an elongated body having a distal end and a proximal end. The distal end of the probe body can be inserted into the gastrointestinal tract through a body orifice. The endoscope may be equipped with optical devices such as cameras or fiber optics to permit observation of the tissues surrounding the distal end, and surgery may be performed by inserting and maneuvering surgical instruments through a channel in the endoscope body. Other probes common...

Claims

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Application Information

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IPC IPC(8): A61B1/31A61B5/042A61B5/05A61B5/06A61B8/08A61B8/12A61B17/00A61B17/22A61B17/32A61B17/34A61B19/00A61F2/958A61M25/00A61M25/01A61M25/095
CPCA61B1/00055A61B1/00059A61B1/00062A61B1/31A61B5/042A61B5/06A61B5/065A61B8/0833A61B8/0841A61B10/02A61B17/22012A61B17/3403A61B17/3415A61B19/44A61B19/52A61B19/5244A61B19/54A61B2017/00482A61B2017/00725A61B2017/22008A61B2018/00178A61B2018/00988A61B2019/4873A61B2019/5251A61B2019/5272A61B2019/5287A61B2019/5429A61B2019/5458A61B2560/0276A61B2562/08A61M25/0023A61M25/0127A61M25/10A61M2025/0025A61M2025/0166A61M2025/1052A61B8/4254A61B90/36A61B2034/2072A61B2090/363A61B34/20A61B90/90A61B2090/0814A61B2034/2051A61B90/39A61B2090/3929A61B2090/3958A61B5/283
Inventor ACKER, DAVID E.BEJERANO, YANIV
Owner BIOSENSE
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