U.S. patent application number 11/184283 was filed with the patent office on 2005-11-10 for capsule type endoscope.
This patent application is currently assigned to OLYMPUS CORPORATION. Invention is credited to Mizuno, Hitoshi.
Application Number | 20050250991 11/184283 |
Document ID | / |
Family ID | 19026214 |
Filed Date | 2005-11-10 |
United States Patent
Application |
20050250991 |
Kind Code |
A1 |
Mizuno, Hitoshi |
November 10, 2005 |
Capsule type endoscope
Abstract
A capsule-type endoscope comprising a capsule body, an image
pickup element, illuminating elements, an image signal processing
circuit, a memory, an image information transmitting circuit and an
antenna for wireless transmission. The capsule body contains the
pickup element, the illuminating elements, the processing circuit,
the memory, transmitting circuit and the antenna. While the capsule
body remains in a living body, the image pickup element takes
images of an interior of the living body. The processing circuit
processes the image, generating image information. The memory
stores the information. The transmitting circuit reads the
information and supplies it to the antenna. The antenna transmits
the information by radio, from the living body.
Inventors: |
Mizuno, Hitoshi;
(Koganei-shi, JP) |
Correspondence
Address: |
SCULLY SCOTT MURPHY & PRESSER, PC
400 GARDEN CITY PLAZA
SUITE 300
GARDEN CITY
NY
11530
US
|
Assignee: |
OLYMPUS CORPORATION
TOKYO
JP
|
Family ID: |
19026214 |
Appl. No.: |
11/184283 |
Filed: |
July 19, 2005 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11184283 |
Jul 19, 2005 |
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10173998 |
Jun 18, 2002 |
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6939292 |
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Current U.S.
Class: |
600/160 ;
600/109; 600/476 |
Current CPC
Class: |
A61B 1/00016 20130101;
A61B 1/042 20130101; A61B 1/041 20130101; A61B 1/0676 20130101;
A61B 5/07 20130101; A61B 1/0607 20130101; A61B 1/0684 20130101;
A61B 5/062 20130101 |
Class at
Publication: |
600/160 ;
600/109; 600/476 |
International
Class: |
A61B 001/04 |
Foreign Application Data
Date |
Code |
Application Number |
Jun 20, 2001 |
JP |
2001-186827 |
Claims
1-42. (canceled)
43. A method of observing an inside of a living body, comprising
the steps of: (a) acquiring an image inside the living body at a
predetermined position, the predetermined position being the start
point of observation; (b) changing the position for acquiring an
image; (c) acquiring an image of the living body at the new
acquiring position; and (d) repeating steps b and c, wherein steps
a to d are performed automatically.
44. The method of observing an inside of a living body according to
claim 43, wherein the image acquired at a new position is such that
it is continuous with the image acquired prior to this
position.
45. The method of observing an inside of a living body according to
claim 44, wherein the direction in which the acquired images are
continued is the direction in which the positions for acquiring the
images change.
46. The method of observing an inside of a living body according to
claim 43, wherein the images are acquired after changing the speed
of acquiring the images.
47. The method of observing an inside of a living body according to
claim 43, wherein a target of acquiring images is a predetermined
internal organ, and then the target organ is changed from the
predetermined organ to another organ, acquiring images stops.
48. The method of observing an inside of a living body according to
claim 47, wherein the predetermined organ is the esophagus and the
other organ is the stomach.
49. The method of observing an inside of a living body according to
claim 43, wherein acquiring images is stopped based on a preset
schedule.
50. The method of observing an inside of a living body, according
to claim 49, wherein the preset schedule is determined based on at
least one of the position for acquiring an image, the time that the
image was acquired, and the number of images that have been
acquired.
51. The method of observing an inside of a living body acquiring to
claim 43, wherein images are stored after being acquired, the image
being compressed to JPEG format in storing the images.
52. The method of observing an inside of a living body according to
claim 43, wherein images are stored after being acquired, and the
stored images are wirelessly transmitted.
53. The method of observing an inside of a living body according to
claim 46, wherein a subject of acquiring images is a predetermined
internal organ, and when the subject organ is changed from the
predetermined organ to another organ, the speed of acquiring the
images is changed.
54. The method of observing an inside of a living body according to
claim 46, wherein the speed of acquiring the images is changed
based on a preset schedule.
55. The method of observing an inside of a living body according to
claim 46, wherein the speed of acquiring the images is changed such
that the acquisition speed after change is less than before
change.
56. The method of observing an inside of a living body according to
claim 43, wherein the speed of acquiring the images is changed in
accordance with the position.
57. The method of observing an inside of a living body acquiring to
claim 43, wherein images are acquired at more than 5
frames/second.
58. The method of observing an inside of a living body acquiring to
claim 52, wherein the speed of acquiring the images is greater than
that of transmitting the images.
59. The method of observing an inside of a living body according to
claim 43, wherein steps a to d are automatically performed in
accordance with a predetermined program.
60. The method of observing an inside of a living body acquired
according to claim 59, wherein the predetermined program is set
before step a.
61. The method of observing an inside of a living body acquiring a
living body according to claim 59, wherein the predetermined
program is changed after step a.
62. The method of observing an inside of a living body according to
claim 46, wherein the speed of acquiring the images is changed to
acquire images of a subject organ of the living body.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is based upon and claims the benefit of
priority from the prior Japanese Patent Application No.
2001-186827, filed Jun. 20, 2001, the entire contents of which are
incorporated herein by reference.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates to a capsule type endoscope
having a capsule body internally equipped with an image taking
device for taking images in the body cavity of a human subject.
[0004] 2. Description of the Related Art
[0005] An endoscope can be inserted into the esophageal canal of
the human subject to directly examine the inner wall of any
affected region of interest with high reliability. However, this
method needs relatively large equipment and, in addition, a large
burden is inflicted on the patient and operator. Therefore, such
conventional endoscopy is hard to adopt in a first screening such
as mass screening.
[0006] As a first screening such as mass screening, in general, it
is usually only necessary to examine the presence or absence of any
affected region of interest at least, and a simpler examination
should be adopted from the standpoint of reduced cost, pain and
psychological unrest.
[0007] Therefore, it has been desired to establish simpler checking
means for adopting a first screening program by which it is
possible to directly and exactly check the esophageal wall for any
affected new region of interest.
[0008] One approach is directed to a camera type of system
according to which an endoscope is formed as a capsule
configuration and, by swallowing such a capsule, images are taken
by that camera-incorporated capsule during its passage through the
esophageal canal to allow the corresponding image signals to be,
for example, wirelessly transmitted to the outside in realtime.
[0009] However, upon image transmission in realtime, the video
frame rate is normally very slow at two frames per second, while,
on the other hand, the time during which the capsule passes through
the esophageal canal is very short, being of the order of one
second. As a result, only about one or two frames can be obtained
during the passage of the capsule through the esophageal canal.
Therefore, adequate reliability can not be ensured at such a frame
rate and hence it is not suitable for the examination of the
esophagus. Further, there has been some inconvenience in that exact
examination of not only the esophagus but also the internal organs
such as the stomach, the duodenum the small intestine and the large
intestine can not be made for any affected region of interest or
its neighborhood.
BRIEF SUMMARY OF THE INVENTION
[0010] It is accordingly the object of the present invention to
provide a capsule type endoscope which can take many more frames of
images for a shorter period in which the capsule passes through an
affected region or its neighborhood, or a region of interest, of
the esophageal canal and internal organs.
[0011] In order to achieve the above object, there is provided a
capsule type endoscope of the present invention having a capsule
body comprising an illuminating unit configured to illuminate the
inside of a living body, an image pickup element configured to take
images in a living body illuminated by the illuminating unit and
generate taken image signals, a processing circuit configured to
process the taken image signals to generate image signals, a memory
configured to store the image signals, a transmitting circuit
configured to take out the image signals from the memory and
convert these image signals to transmission signals, and an antenna
configured to wirelessly transmit these transmission signals to the
outside of the living body, wherein the image signals generated
from the processing circuit are stored in the memory, the image
signals stored in the memory are converted to transmission signals
by the transmitting circuit and the transmission signals are
wirelessly transmitted to the outside by the antenna.
[0012] It is, therefore, possible to take many more frames of
images in a shorter period of time during which the capsule passes
through the esophageal canal and obtain added reliability on
examination.
[0013] Additional objects and advantages of the invention will be
set forth in the description which follows, and in part will be
obvious from the description, or may be learned by practice of the
invention. The objects and advantages of the invention may be
realized and obtained by means of the instrumentalities and
combinations particularly pointed out hereinafter.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING
[0014] The accompanying drawings, which are incorporated in and
constitute a part of the specification, illustrate presently
preferred embodiments of the invention, and together with the
general description given above and the detailed description of the
preferred embodiments given below, serve to explain the principles
of the invention.
[0015] FIG. 1 is a view in longitudinal cross-section
diagrammatically showing a capsule type endoscope according to a
first embodiment of the present invention;
[0016] FIG. 2 is a view in transverse cross-section
diagrammatically showing a capsule type endoscope according to the
first embodiment of the present invention;
[0017] FIG. 3 is a diagrammatic view showing a receiver installed
outside a living body relative to the first embodiment of the
present invention;
[0018] FIG. 4A is an explanatory view showing the capsule type
endoscope in use which is based on the first embodiment of the
present invention;
[0019] FIG. 4B is a transverse cross-sectional view as taken along
line 4B-4B in FIG. 4A;
[0020] FIG. 5 is an explanatory view showing a circuit arrangement
of the capsule type endoscope according to the first embodiment of
the present invention;
[0021] FIG. 6 is a view in longitudinal cross-section
diagrammatically showing a capsule type endoscope according to a
second embodiment of the present invention;
[0022] FIG. 7 is a view in longitudinal cross-section
diagrammatically showing a capsule type endoscope according to a
third embodiment of the present invention;
[0023] FIG. 8 is a view in longitudinal cross-section
diagrammatically showing a capsule type endoscope according to a
fourth embodiment of the present invention;
[0024] FIG. 9 is a view in longitudinal cross-section
diagrammatically showing a capsule type endoscope according to a
fifth embodiment of the present invention;
[0025] FIG. 10 is a side view showing a capsule type endoscope
according to a sixth embodiment of the present invention; and
[0026] FIG. 11 is a plan view showing the capsule type endoscope
according to the sixth embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
First Embodiment
[0027] A capsule type endoscope according to a first embodiment of
the present invention will be described below by referring to FIGS.
1 to 5.
[0028] FIG. 1 is a diagrammatic view showing a capsule type
endoscope 1 configured as a so-called compact camera. The endoscope
has a light-transparent capsule body 2 serving as a protective
outer shell. The capsule body 2 is formed as a case having such an
outer configuration and size that it can be passed through the
esophageal canal upon being swallowed via the mouth. A sealed
storage chamber is created within the capsule body 2. As shown in
FIG. 1, the capsule body 2 has a cylindrical intermediate section
axially elongated compared with its diameter. Both the opposite end
sections of the capsule body 2, are each formed to have an axially
outwardly extending hollow semispherical configuration with at
least its outer surface smoothly formed. Since the capsule body 2
is formed as being axially elongated compared with the diameter, it
can be easily swallowed and the swallowing movement direction is
readily liable to be guided toward the axial direction of the
capsule body 2.
[0029] As shown in FIG. 1, various kinds of associated component
parts are incorporated within the storage chamber of the capsule
body. Within the capsule body 2 are stored a substrate 3, an image
taking device having an image pickup element 4 and illuminating
elements 5 mounted on the substrate, an image (video) signal
processing circuit 6, a memory 7, an image (video) signal
transmitting circuit 8, a battery 9, an antenna 10, a position
detecting means 11, etc.
[0030] As the image pickup element 4 use is made of a solid state
image pickup element such as a C-MOS and a CCD. As the illuminating
elements 5 use is made of, for example, LEDs and so on. As shown in
FIG. 2, the illuminating elements 5 are equidistantly arranged
around the image pickup element 4. Each illuminating light emitted
from the corresponding illuminating element 5 is radiated onto an
image taking field through a transparent end wall of the capsule
body 2 to illuminate the image taking field. The image pickup
element 4 takes images in the illuminated image taking field.
[0031] The image signal processing circuit 6 processes signals
taken by the image taking element 4 in the image taking device to
generate image signals. The signals are supplied to a memory 7
where these signals are once stored. The stored image signals are
sequentially taken out by the image signal transmitting circuit 8
and sequentially converted to transmission signals. The
transmission signals are sequentially transmitted via the antenna
10 to the outside by wireless. The battery 9 is used as a power
source for each element, circuits and so on.
[0032] The position detecting means 11 has a sensor for detecting
an electromagnetic field at its site and detects the position of
the capsule body 2 by the electromagnetic field detected by the
sensor. For example, it responds to an external plate 12, such as a
magnetic plate or conductive plate, as will be set out below to
detect the external plate 12 and decides its own position. Further,
it may be made to respond to an electromagnetic field generated in
a magnetic coil if the external plate placed outside the living
body is replaced by the magnetic coil.
[0033] FIG. 3 shows a receiver 15 located outside the living body.
The receiver 15 receives/records image signals sent by a wireless
transmission from the capsule type endoscope 1. The receiver 15
includes a receiving antenna 16, an image signal receiving circuit
17 and an image recording means (memory) 18. The image signals
received by the image signal receiving circuit 17 are recorded in
the image recording means 18. The image recording means 18
transmits the image signals to a monitor 19 where these images are
monitored. The images taken can also be transmitted to a given
image receiver at a remote site via a communication means such as
the Internet (not shown).
[0034] It is to be noted that a program capable of a variable
setting is provided for the image pickup element 4, image
information transmitting circuit 8, image signal processing circuit
6 and memory 7. The image taking rate by the image pickup element
4, the transmission rate by the image information transmitting
circuit 8, the timing and time for allowing the storing of the
image signals into the memory 7 through the image signal processing
circuit 6 are arbitrarily set or variable by being programmable.
These may be settable or variable even in such cases as to varying
the program of a timer, etc., in the capsule body 2 before
swallowing the capsule body 2, to vary a program by information
from outside the living body after the capsule body 2 has been
swallowed, or to vary both. In this case, a receiver 41 and antenna
42 are provided in the capsule body 2 as shown in FIG. 1 to receive
information for instructing a variation of the information
contents.
[0035] Now, an explanation will be made below about how to use the
capsule type endoscope 1 set out above. First, as shown in FIG. 4A,
the external plate 12 is positioned in a manner to correspond to
the esophageal canal 21 of a patient 20 and it is located on the
external surface of the patient 20.
[0036] After this, the capsule type endoscope 1 is swallowed via
the mouth with its axial direction guided toward the swallowing
movement direction.
[0037] As shown in FIG. 4A, the capsule type endoscope 1 passes
through the esophageal canal 21 with its longitudinal axis
direction guided toward the longitudinal direction of the
esophageal canal 21. When the capsule type endoscope 1 passes
through the esophageal canal 21, the position detecting means 11 of
the capsule type endoscope 1 senses the external plate 12 and the
image taking device starts its operation. The position detecting
means 11, while sensing the external plate 12, decides that the
capsule type endoscope 1 is situated in the esophageal canal
21.
[0038] As shown in FIGS. 4A and 4B, while the capsule endoscope 1
is detected as being situated in the esophageal canal 21, the
illuminating elements 5 are lit and the image taking device is
intermittently operated. The area of the esophageal canal 21 thus
illuminated is thereby imaged by the image pickup element 4 many
number of times.
[0039] The capsule type endoscope 1 can pass through the esophageal
canal 21, usually within a very short time of one second. During
this short time, the image pickup element 4 takes many frames of an
image at high speeds, while scanning the entire area of the
esophageal canal 21. The minimum frame rate required for
continuously scanning the entire area of the esophageal canal 21 is
5 frames/second. Assume that the canal 21 is 30 cm long as in most
cases, that the focal depth of the endoscope 1 is 6 cm and that it
takes the endoscope 1 one second to pass the canal 21. Then, the
minimum frame rate is given as:
30(cm)/6(cm)/1(sec)=5 frames/second
[0040] The length of the esophageal canal varies from person to
person, and the focal depth of the endoscope 1 may change from time
to time. If the endoscope 1 needs 0.5 seconds to pass through the
canal 21, the focal depth of the endoscope 1 is 1 cm, and 30 frames
(=30(cm)/1(cm)) must be taken, then the frame rate should be 60
frames/second.
[0041] However, if the frame rate is less than 5 frames/second, for
example 2 frames/second, it is not easy to set the focal depth at
10 cm or more. It is therefore hard to set the far point at 10 cm
or more for tubular organs such as the esophageal canal.
Consequently, it would be difficult to observe the esophageal canal
continuously. However hard the patient tries, he or she cannot
swallow the capsule to move it continuously and slowly through the
entire esophageal canal. In view of this, the imaging of the canal
must be carried out at a frame rate of at least 5 frames/second to
achieve continuous observation of the entire area of the esophageal
canal 21.
[0042] Further, the image signal processing circuit 6 sequentially
processes those signals taken by the image pickup element 4 to
generate image signals, and these image signals are stored in the
memory 7 in realtime. For example, an image of a hundred thousand
pixels is compressed under the JPEG system and those images
corresponding to 30 frames are sequentially retained in the memory
7. Here, recording rate at which the generated image signal is
stored in the memory 7 in realtime is given by V1.
[0043] After the capsule type endoscope has dropped past the
esophageal canal 21 into the stomach, the image taking operation is
stopped because the position detecting means 11 ceases to detect
the external plate 12. Thus, the capsule type endoscope 1 performs
a high-speed image taking operation only during the time in which
it passes through the esophageal canal. Since the capsule type
endoscope stops its image taking operation after it has dropped
into the stomach and does not continue its image taking operation,
the capacity of the memory 7 can be effectively utilized without
wasting it. Further, the remaining capacity of the memory 7 can be
kept for another image taking operation.
[0044] Although the signals of those images taken by the image
pickup element 4 of the image taking device have been once stored
in the memory 7, the image information items are sequentially read
out of the memory 7 and wirelessly transmitted by the image signal
transmitting circuit 8 to the outside of the living body via the
antenna 10. The operation of storing the signals of the images
taken by the image pickup element 4 is continued without waiting
for the completion of the transmission of the previous image
information items by the image signal transmitting circuit 8 and
these are sequentially stored in the memory 7.
[0045] Incidentally, the transmitting speed V2 by the image signal
transmitting circuit 8 is as slow as a frame rate of two
frames/second. However, the signals of the images taken by the
image taking element 4 continue their storing operation relative to
the memory 7 without waiting for the completion of the transmission
operation. That is, since the image signal taking operation while
allowing the transmitting operation is continued, a larger amount
of image signals can be stored in the memory 7. Even if the
transmitting rate V2 is slower than the recording rate V1, it is
possible to make the recording rate V1 fairly rapid.
[0046] Further, the image signals stored in the memory 7 are
wirelessly transmitted by the image signal transmitting circuit 8
to the outside of the living body via the antenna 10 in the order
in which these image signals are stored.
[0047] The operation of storing the image signals into the memory 7
and the transmitting operation by the image signal transmitting
circuit 8 are carried out individually. A greater amount of image
signals is stored for a shorter time period into the memory 7 and
the image signals stored in the memory 7 are sequentially
transmitted by the image signal transmitting circuit 8 to the
outside of the living body in a wireless fashion.
[0048] On the other hand, the receiver 15 externally installed as
shown in FIG. 3 receives the image signals via the receiving
antenna 16 which are transmitted from the capsule type endoscope 1
and the image signals are recorded via the image signal receiving
circuit 17 into the image recording means 18. Further, the image
signals are transmitted to the monitor 19 where these images are
monitored or to an image receiver at a remote site through a
communication means such as the Internet (not shown).
[0049] The position detecting means 11 as set out above detects the
position of the capsule body 2, and the image taking time, the
times of image taking, and so on, are controlled. By doing so it is
possible to adopt various kinds of image taking modes. For example,
when the capsule body passes through the position corresponding to
the external plate 12, images are taken at a frame rate of 60
frames/second and, after the passage of the capsule body past that
corresponding position, switching is made to a mode in which images
are obtained at a frame rate of 2 frames/second. By doing so,
proper image taking is carried out in accordance with each
site.
[0050] Although, in the above-mentioned embodiment, the position
detecting means 11 detects the external plate 12 to decide a
position corresponding to the location of the capsule type
endoscope 1, this invention is not restricted thereto and it is
also possible to decide the position of the capsule type endoscope
with the use of other position detecting systems. Further, the
position detecting means as set out above may be comprised of a
gyro, an acceleration sensor, a sensor for detecting the moving
speed of the capsule body 2, and so on.
[0051] Further, the position detected by the position detecting
means 11 may be stored as position information in the memory 43 and
the position information may be wirelessly transmitted to the
outside by the transmitting unit 45 including an antenna 44. Still
further, an adjusting unit 48 may be provided for adjusting the
image taking rate by the image pickup element 4, the ON/OFF
operation of the image taking, and so on, according to the position
information of the capsule body 2 detected by the detecting means
11 as shown in FIG. 1.
Second Embodiment
[0052] An explanation will be made below about a capsule type
endoscope according to a second embodiment of the present invention
by referring to FIG. 6. The capsule type endoscope 1 of this
invention includes a built-in timer 31 in a capsule body 2, and, by
means of this timer 31, the image taking time and the times of
image taking by an image taking device, and so on, are controlled
based both on its time data and according to a timer program. The
remaining structure is the same as that of the first
embodiment.
[0053] Based on the time data of the timer 31 and according to the
timer program, the image taking time, the times of image taking,
and so on, can be controlled and, by doing so, various modes of
image taking can be adopted. For example, the capsule type
endoscope 1, after being passed through the esophageal canal 21, is
discharged via the anus past the stomach, the small intestine and
the large intestine but it takes a whole day and night, unlike the
passage of the capsule type endoscope through the esophageal canal,
to move the capsule type endoscope through the stomach, the small
intestine and the large intestine. For this reason, the image
taking rate is varied or ON/OFF operated according to a schedule
initially set by the timer 31 and, by doing so, it is possible to
effectively utilize a data retaining capacity in the memory 7 and
also to reduce the wastage of the battery 9 for lighting
illuminating means. An image taking examination can be made over
the whole alimentary canal, including a gastrointestinal image
taking examination after the capsule type endoscope has passed
through the esophageal canal 21.
Third Embodiment
[0054] An explanation will be made below about a capsule type
endoscope according to a third embodiment of the present invention
by referring to FIG. 7. In the capsule type endoscope 1 according
to this embodiment, the center of gravity, W, is located at or near
a position corresponding to the image pickup element 4. Here, it is
located on a longitudinal axis of the capsule body 2 at a position
where the substrate 3 is situated. That is, the center of gravity,
W, of the capsule type endoscope 1 is located at a forward site of
the capsule body 2 on the image pickup element 4 side. The position
of gravity, W is determined depending upon the shape and material
of the capsule body 2 as well as the size and number of built-in
component parts and their locations, and so on, and it is
determined from the standpoint of these design considerations.
[0055] Since the center of gravity, W, of the capsule type
endoscope 1 is located at the forward site of the capsule body 2 on
the image pickup element 4 side, the capsule type endoscope 1 is
easier to swallow and, after being swallowed, the direction of the
capsule body 2 is stably guided and it is possible to stably and
positively take images in the esophageal canal.
Fourth Embodiment
[0056] An explanation will be made below about a capsule type
endoscope according to a fourth embodiment of the present invention
by referring to FIG. 8. In the capsule type endoscope 1 of the
fourth embodiment, its capsule body 2 is so formed as to have a
semi-spherical configuration at the forward end section as viewed
from its longitudinal direction and the backward end section of the
capsule body 2 is so formed as to be gradually tapered toward a
backward direction. The forward end section of the capsule body 2
is larger in diameter than the backward end section. If the capsule
body 2 is made thicker on the forward end side, then the center of
gravity, W, of the capsule type endoscope 1 tends to be located
toward the forward section of the capsule body 2. Since the capsule
body 2 has such a shape as set out above, it is easier to swallow
toward a predetermined direction.
Fifth Embodiment
[0057] An explanation will be made below about a capsule type
endoscope according to a fifth embodiment of the present invention
by referring to FIG. 9. In the capsule type endoscope 1 according
to this embodiment, its capsule body 2 is so formed as to have
image taking devices incorporated at opposite longitudinal end
portions. By so doing it is possible to take images at both the
longitudinal forward and backward sections of the capsule body 2.
The respective image taking device is so formed as to have its
corresponding image pickup element 4 and illuminating elements 5
mounted on a corresponding substrate 3.
[0058] According to the thus structured capsule type endoscope 1,
when the capsule body 2 is swallowed, it is possible to take images
not only at its forward section but also at its backward section as
viewed in its moving direction and, hence, to take more images
corresponding to more sites of interest. In addition, it is also
possible to take images corresponding to the inner wall sites of
the esophageal canal from different directions. As a result, more
reliability is ensured on diagnosis.
[0059] Since the backward sites can be taken as images when the
capsule body 2 is swallowed, it is possible to take images at an
important region of interest just at or near the exit opening of
the esophagus into the stomach, in particular, immediately before,
and just at the moment of, the dropping of the capsule body 2 into
the stomach.
Sixth Embodiment
[0060] An explanation will be made below about a capsule type
endoscope according to a sixth embodiment of the present invention
by referring to FIGS. 10 and 11. In the capsule type endoscope 1 of
this embodiment, a capsule body 2 has a soft flat tail 35 at its
backward portion.
[0061] According to the capsule type endoscope 1 having such a tail
35, the capsule body 2 is easier to swallow and, when the capsule
type endoscope 1 has been swallowed, the direction of the capsule
body 2 is stably oriented by the tail 35 and it is possible to
positively take images of the inner wall of the esophageal
canal.
[0062] It is to be noted that the present invention set out above
is not restricted to the above-mentioned respective embodiments and
can be applied to other modes of application. Although, in the
above-mentioned embodiments, the explanation has been made more
about taking images of the inner wall of the esophageal canal, the
object of the image taking is not restricted to the esophagus and
the present invention can be applied to image taking of a region of
interest to examine not only the esophagus but also those organs
such as the stomach, the small intestine and the large intestine
for any affected region of interest and its neighborhood. In this
case, it is only necessary to set the position of the position
detecting means and program of the timer to the region of
interest.
[0063] The present invention is not limited to the capsule type
endoscope described above, which has a battery in the capsule body
to supply power to the elements and circuits provided in the
endoscope. Rather, the invention may be applied to a capsule type
endoscope shown in FIG. 6, in which a power receiver 46 is provided
in the capsule body 2. The receiver 46 continuously receives power
that is supplied from the outside in the form of electromagnetic
waves, for example, microwaves or light that passes through the
living tissues and organs. Further, a battery may be provided for
storing electric power received by the power receiver 46 or may be
made rechargeable. According to such a structure, the electric
power can be continuously supplied in a contactless way from
outside to the capsule type endoscope in a living body and there is
the advantage that the capsule type endoscope in the living body
can be positively operated for a long time. Stated in more detail,
the capsule body has a built-in power receiving means such as a
power receiving antenna or a solar cell unit and, outside the
living body, a power transmitting antenna or light emitting means
as a light emitting plate/light emitting unit is arranged toward
the inside of the living body.
[0064] Additional advantages and modifications will readily occur
to those skilled in the art. Therefore, the invention in its
broader aspects is not limited to the specific details and
representative embodiments shown and described herein. Accordingly,
various modifications may be made without departing from the spirit
or scope of the general inventive concept as defined by the
appended claims and their equivalents.
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