The present invention relates to medical devices in general, and in particular to imaging endoscopes.
One of the most common methods for non-invasively screening an internal body cavity of a patient is with an imaging endoscope. Such endoscopes are elongated devices that are inserted into the body cavity. Light is delivered through an illumination channel of the endoscope and reflected light is gathered by one or more lenses that are coupled to an imaging channel. Light from the imaging channel is transmitted out of the endoscope and supplied to a camera or other viewing device so that a physician can examine the internal body tissue. Typical cameras connected to the endoscope typically include a solid state image sensor such as a CCD array.
One problem with conventional imaging endoscopes is their relatively low resolution. For example, on a 3.5 mm square CCD array, the resolution is limited to approximately 850K pixels. Another problem is their high cost. At a current price of approximately $350 each, the cost of such image sensors alone makes it impractical to design single use or disposable endoscopes. Instead, such endoscopes need to be sterilizable so they can be used on many different patients. In order to withstand the high temperature and/or harsh chemical environment used in sterilization, conventional endoscopes are made to be relatively stiff and rugged. However, the same factors that contribute to the long life of an endoscope also reduce its ability to be inserted into some body cavities. Therefore, there is a need for an endoscope that has a higher resolution and can be manufactured at a cost that makes it practical to be a single use item.
To address these and other concerns, the present invention is an imaging endoscope having a light beam directing mechanism for steering a beam of illumination light over an area of interest. Light reflected from tissue in the area of interest is received by a photo sensor that converts the light into a corresponding electrical signal. Electrical signals are combined in an image processor to produce an image of the tissue.
In one embodiment of the invention, the light deflecting mechanism comprises a pair of mirrors that are moved by oscillating microelectrical machines (MEMS) that steer the light in a raster fashion over the area of interest. In one embodiment, light is directed to the moving mirrors via an input optical fiber that extends from a proximal end to a distal end of the endoscope.
Images of tissue can be stored in a database and analyzed by a computer to determine the likelihood that an image contains a particular type of tissue such as a cancerous lesion. If a lesion is detected, the intensity of the illumination light may be selectively increased to ablate the tissue in situ. A display is provided to show a physician or other user the image of the tissue.
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
One of the benefits of the endoscope 12 is that because it lacks a camera chip within the endoscope itself, it can be made for a sufficiently low cost such that it can be considered a single use or disposable item. Therefore, the costs associated with sterilizing the endoscope are not incurred for the user. Furthermore, the endoscope 12 can be made more flexible than conventional endoscopes because it does not need to withstand the high temperatures or other harsh chemical environments typically required for sterilizable endoscopes.
If the physician sees a tissue sample that appears cancerous or should otherwise be removed from the patient, the physician adjusts an intensity control 18 of the light source 14. By adjusting the light source to a sufficient intensity, any suspicious tissue can be ablated in situ. For example, if the light source 14 comprises a laser, the power of the laser can be selectively increased or decreased by the intensity control 18 to ablate the tissue or collect images.
As an aid to diagnosing tissue samples viewed by the physician, the image processor/computer 22 can analyze images of the tissue to determine if they represent cancerous or other particular tissue types. Such analysis by the processor/computer types can be based on the pathology of known lesions. Dyes or other markers of specific tissue types can be detected by the image processor/computer and used to identify the tissue type. Alternatively, an image can be measured by the image processor/computer 22 according to a number of criteria such as the length, roundness, eccentricity, texture or other morphological features known by image cytometrists to highlight or identify particular tissue types. New images of a tissue sample can be compared against these criteria and potentially suspicious tissue can be highlighted on the display 24 for a physician to view prior to determining whether the tissue should be ablated or removed surgically.
The beam deflection mechanism 50 is preferably made of one or more microelectronic machines (MEMS) that are inexpensive enough to manufacture such that the endoscope 12 can be considered a single use or disposable item. Details of one suitable mechanism for driving the mirrors 54, 56 are fully described in U.S. Pat. Nos. 6,245,590 and 6,331,909, assigned to Microvision, Inc. of Bothell, Wash. and herein incorporated by reference. However, it will be appreciated that there are other mechanisms for moving the mirrors, including electric motors, piezoelectric crystals or other devices that can move the mirrors to move the illumination light over an area with a repeating pattern that may be other than a raster pattern.
The photo detector 20 as shown in
While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention. For example, it is possible to incorporate a solid state light source or other light emitting device near the distal end of the endoscope and to eliminate the need for an input optical fiber to transfer light from an external light source to the beam deflection mechanism. Similarly, the light sensor could be located within the endoscope itself to eliminate the optical fiber that carries reflected light out of the endoscope. One or more lenses would direct reflected light into the sensor and wires would carry the corresponding electrical signals to a remote image processor/computer. Therefore, the scope of the invention is to be determined from the following claims and equivalents thereof.
Number | Date | Country | |
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Parent | 10639040 | Aug 2003 | US |
Child | 11964613 | US |