PH12017000281A1 - MAGNETICALLY MANEUVERABLE LAPAROSCOPIC CAMERA SYSTEM 360ø - Google Patents

Abstract

A laparoscopic camera system includes a camera device (1 0) that has a spherical outer shell (11) designed to be introduced inside a patient's abdomen through an incision made on the umbilicus advanced down to the peritoneum. Multiple camera modules (12) and multiple light sources (13) are distributed at the outer shell (11). A magnetic maneuvering system (14) is disposed within the outer shell (11) to enable maneuvering and anchoring of the camera device (10) inside the patient's abdomen via magnetism. A wireless module (15), which is also disposed within the outer shell (11), is configured to wirelessly transmit camera images.

Description

Pot fom and 4B), and a pouch component (48) coupled to the retrieval shaft (47) and configured for retrieving the camera device (10) from the patient’s abdomen. +s oo i

Referring to FIGURE 6, once the camera device (10) has been positioned to the desired area of, the abdominal wall, the handle device (20) located outside the abdomen can be turned on and bg magnetically attached to the camera device (10). Once attached, the second knob (46) of the placemerit’ device (40) can be operated to release the camera device (10) from the loop component (45). The handle device (20) controls the camera device (10) and its functions wirelessly. Once the surgical procedure is done, the handle device (20) can be turned off to detach the camera device (10), and the pouch component (48) can be used to catch the camera device (10) for removal from the patient’s abdomen via the top valve part (311).

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Field of the Invention oo

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The present invention relates to a laparoscopic camera system for use in minimally invasive surgery. Specifically, the laparoscopic camera system can be inserted into the abdominal cavity of a surgical patient using only a single umbilical incision for use in laparoscopic surgical procedures, providing more efficient performance of several laparoscopic surgical procedures with the ability of a 360° view of the surgical field while performing the procedures.

Background of the Invention

Laparoscopic Surgery is also called minimally invasive surgery of the abdomen that is performed using a laparoscope. Traditionally, it is being done with either 3 or 4 incisions where trocars are inserted for laparoscopic instruments while the laparoscope is inserted thru the umbilicus. The newer technique involves using Single Incision Laparoscopic Surgery (SILS) where all trocars, instruments, including the laparoscope are inserted thru only one incision. SILS has now become the choice of patients mainly because of its better aesthetic outcome. However, with SILS, there is limited visualization and mobility due to the effect of a restricted space. This leads to increased difficulty of the surgical procedure, lengthier time of completion, and more risks for the patient. Therefore, improvements are needed in the surgical technique, systems, and devices in relation to single incision laparoscopic surgery.

The present invention was designed to address the said difficulties. Features of this invention include the ability of having 360° view of the surgical field while performing the procedure, maneuverability with sustained stability while being attached magnetically to an external handle device, and wireless connectivity while only using a single umbilical incision. With this, there is now enough space for the surgeon to perform procedures better, faster, and safer with fewer scars.

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Summary of the Invention jo

According to one aspect of the invention, a laparoscopic camera system comprises a camera device that includes: a spherical outer shell designed to be introduced inside a patient’s abdomen through an incision made on the umbilicus advanced down to the peritoneum; multiple camera modules distributed at the outer shell; multiple light sources distributed at the outer shell for illumination of visual fields of the camera modules; a magnetic maneuvering system within the outer shell to enable maneuvering and anchoring of the camera device inside the patient’s abdomen via magnetism; and a wireless module within the outer shell and configured to wirelessly transmit camera images.

In one embodiment, the camera device further includes a rechargeable power module having a power button and a charging port both disposed at the outer shell. The power button is operable to turn on and turn off the camera device.

In one embodiment, the camera modules are distributed at the outer shell to attain different angles of visualization and enable a full 360° view of the abdominal cavity.

In one embodiment, the laparoscopic camera system further comprises a handle device that includes: a device body designed to be hand held and positioned outside the abdomen; and a magnetic base connected to the device body and configured to cooperate with the magnetic maneuvering system of the camera device to maneuver and anchor the camera device in the patient’s abdomen.

In one embodiment, the camera modules are variable zoom modules, the device body is provided with zoom control buttons, the handle device further includes a wireless control module configured to transmit wireless control signals associated with operation of the zoom control buttons, and the wireless module is configured to receive the wireless control signals from the wireless control module and to perform zoom control of the camera modules according to the wireless control signals.

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In one embodiment, the handle device further includes a rechargeable power module having:a power button and a charging port both disposed at the device body. The power button is operable fo turn on and turn off the handle device. o a

In one embodiment, the handle device further includes at least one strap provided on the device body to secure the hand of the user on the device body.

In one embodiment, the laparoscopic camera system further comprises a port device that includes a camera port component and a sleeve connector component. The camera port component includes a cylindrical port body, a top valve part located at a top end of the cylindrical port body to serve as a passageway for the camera device into the abdominal cavity, multiple instrument ports distributed on the cylindrical port body for passage of laparoscopic instruments, a push-vent located on the cylindrical port body and operable to release cauterization smoke from the abdominal cavity, and an insufflation port located on the cylindrical port body to serve as a passageway for insufflating air. The sleeve connector component includes an elastic sleeve body with a top part coupled to a bottom part of the cylindrical port body. The elastic sleeve body is configured for insertion through the incision made on the umbilicus down to the peritoneum.

In one embodiment, the laparoscopic camera system further comprises a placement device that includes a handle, a placement shaft connected to the handle and having a bendable joint, a first knob provided on the handle and operable to bend the placement shaft at the bendable joint, a loop component coupled to the placement shaft, and a second knob provided on the handle and operable to tighten the loop component on the camera device or loosen the loop component from the camera device. Preferably, the placement shaft is connected removably to the handle, and the placement device further includes a retrieval shaft connected removably to the handle, and a pouch component coupled to the retrieval shaft and configured for retrieving the camera device from the patient’s abdomen.

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Brief Description of the Drawings fe

FIGURE 1 is a schematic view of an embodiment of a camera device of the magnetically maneuverable laparoscopic camera system according to the invention. ©

FIGURES 2A and 2B are schematic views of an embodiment of a handle device of the magnetically’ maneuverable laparoscopic camera system according to the invention.

FIGURE 3 is a perspective view of an embodiment of a port device of the magnetically maneuverable laparoscopic camera system according to the invention.

FIGURES 4A and 4B are perspective views of an embodiment of a placement device of the magnetically maneuverable laparoscopic camera system according to the invention.

FIGURE 4C is a perspective view of a retrieval shaft and a pouch component of the placement device.

FIGURES 5A and 5B show Augmented Reality glasses for use with the embodiment.

FIGURE 6 illustrates the magnetically maneuverable laparoscopic camera system in a state of use.

Detailed Description of the Embodiment

Referring to Figures 1, 2A, 2B, 3, 4A, 4B, and 4C, an embodiment of a magnetically maneuverable laparoscopic camera system according to the invention is shown to comprise a camera device (10), a handle device (20), a port device (30) and a placement device (40).

The camera device (10) includes a spherical outer shell (11), multiple camera modules (12), multiple light sources (13), a magnetic maneuvering system (14) and a wireless module (15).

The spherical outer shell (11) is designed to be introduced inside a patient’s abdomen through an incision made on the umbilicus advanced down to the peritoneum. The outer shell (11) is 30-35 mm in diameter, is configured to be waterproof and dustproof, i.e. entry of liquids and other contaminants

. = vo pte frees can be prevented, and can withstand the environment of the abdominal cavity and maintain patient safety. Fa

The camera modules (12) are distributed at the outer shell (11). In this embodiment, the camer, =) modules (12) are purposely distributed evenly throughout the outer shell (11). In particular, each camera module (12) has a camera opening demarcated from equally distributed locations on the’ exterior surface of the outer shell (11) for the purpose of attaining different angles of visualization and enabling a full 360° view of the abdominal cavity. In this embodiment, the camera modules (12) are variable zoom modules with built-in optical image stabilization and anti-fog feature.

The light sources (13), which are LED lights in this embodiment, are strategically distributed at the outer shell (11) in relation to the placement of the camera modules (12) for illumination of visual fields of the camera modules (12).

The magnetic maneuvering system (14) is disposed within the outer shell (11) and functions as an attachment component that enables maneuvering and anchoring of the camera device (10) inside the patient’s abdomen via magnetism.

The wireless module (15) is disposed within the outer shell (11) and is configured to wirelessly transmit camera images. The camera images may be displayed by high-resolution monitors (not shown) or Augmented Reality glasses (50) (FIGURES 5A and 5B).

In this embodiment, the camera device (10) further includes a rechargeable power module having a power button (16) and a charging port (17) both disposed at the outer shell (11). The power button (16) is operable to turn on and turn off the camera device (10). The charging port (17) is for charging an internal rechargeable power source (not shown).

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Referring to FIGURES 2A and 2B, the handle device (20) includes a device body (21) designed to be hand held and positioned outside the abdomen, and a magnetic base (22) connected to the device body (21) and configured to cooperate with the magnetic maneuvering system (14) of the cage device (10) to maneuver and anchor the camera device (10) in the patient’s abdomen, i.e. the abdominal wall (A) is between the magnetic base (22) and the camera device (10). In this embodiment, the device body (21) is provided with zoom control buttons, i.e. a zoom-in button (23) and a zoom-out button (24), and the handle device (20) further includes a wireless control module (25) configured to transmit wireless control signals associated with operation of the zoom control buttons (23, 24). In this embodiment, the buttons (23, 24) are located at a front area of the device body (21) and are accessible to the index finger of the user. The wireless module (15) of the camera device (10) is configured to receive the wireless control signals from the wireless control module (25) and to perform zoom control of the camera modules (12) according to the wireless control signals.

In this embodiment, the handle device (20) further includes a rechargeable power module having a power button (26) located at the left lower side of the device body (21) and a charging port (27) located at the left median side of the device body (21). The power button (26) is operable to turn on and turn off the handle device (20).

In this embodiment, the handle device (20) further includes a thumb strap (28) located at the left upper side of the device body (21) and a front strap (29) located at the lower half of the front area of the device body (21) to secure the thumb and fingers of the user on the device body (21).

In this embodiment, the device body (21) has a top panel (210) provided with different function buttons/indicators such as: a manual motion lever (211) for visual field control; light intensity buttons (212) to increase or reduce illumination by the light sources (13); a light intensity bar (213) to indicate intensity of the illumination output; menu, mode, select and enter buttons (214, 215, 216, 217) for manually selecting Augmented Reality features and applications and other software as tools readily

. ps available during surgery; and an energy bar (218) to indicate remaining power of the handle device

Referring to FIGURE 3, the port device (30) includes a camera port component (31) anda sleeve connector component (32). The camera port component (31) includes a cylindrical port body, (310) made of polyethylene, a top valve part (311) located at a top end of the cylindrical port body (310) to serve as a passageway for the camera device (10) into the abdominal cavity, multiple instrument ports (312) strategically distributed and positioned along the sides of the cylindrical port body (310) for passage of laparoscopic instruments, a push-vent (313) located on the cylindrical port body (310) and operable to release cauterization smoke from the abdominal cavity, and an insufflation port (314) located on the cylindrical port body (310) to serve as a passageway for insufflating air. The sleeve connector component (32) includes an elastic sleeve body (320) with a top part (321) coupled to a bottom part (315) of the cylindrical port body (310). The elastic sleeve body (320), which is made of polyethylene in this embodiment, is configured for insertion through the incision made on the umbilicus down to the peritoneum and has a bendable base (322) and a pull cord (323) connected to the bendable base (322).

Referring to FIGURES 4A and 4B, the placement device (40) is used to place the camera device (10) at the desired location on the abdominal wall beneath the handle device (20). The placement device (40) includes a handle (41), a placement shaft (42) connected to the handle (41) and having a bendable joint (43), a first knob (44) provided on the handle (41) and operable to bend the placement shaft (42) at the bendable joint (43), a loop component (45) coupled to the placement shaft (42), and a second knob (46) provided on the handle (41) and operable to tighten the loop component (45) on the camera device (10) or loosen the loop component (45) from the camera device (10).

In this embodiment, the placement device (40) includes a connector (49) for connecting removably the placement shaft (42) to the handle (41). As shown in FIGURE 4C, the placement device (40) further includes a retrieval shaft (47) connected removably to the connector (49) (FIGURES 4A

Claims (10)

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1. A laparoscopic camera system comprising a camera device (10) that includes: o a spherical outer shell (11)“designed to be introduced inside a patient’s abdomen through aa incision made on the umbilicus advanced down to the peritoneum; = multiple camera modules (12) distributed at the outer shell (11); ” multiple light sources (13y distributed at the outer shell (11) for illumination of visual fields of the camera modules (12); "a magnetic maneuvering system (14) within the outer shell (11) to enable maneuvering and anchoring of the camera device (10) inside the patient’s abdomen via magnetism; and ¥ a wireless module (15) within the outer shell (11) and configured to wirelessly transmit camera images. ]

2) The laparoscopic camera system of claim 1, wherein the camera device (10) further includes a rechargeable power module having a power button (16) and a charging port (17) both disposed at the outer shell (11), the power button (16) being operable to turn on and turn off the camera device (10). tr

3. The laparoscopic camera system of claim 1, wherein the camera modules (12) are distributed at the outer shell (11) to attain different angles of visualization and enable a full 360° view of the abdominal cavity.

4. The laparoscopic camera system of claim 1, further comprising a handle device (20) that includes: a device body (21) designed to be hand held and positioned outside the abdomen; and a magnetic base (22) cefinected to the device body én) and configured to cooperate with the magnetic maneuvering system (14) of the camera device (10) to maneuver and anchor the camera device (10) in the patient’s abdomen.

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5. The laparoscopic camera system of claim 4, wherein the camera modules (12) are variable zoofh modules, the device body (21) is provided with zoom control buttons (23, 24), the handle device 20 further includes a wireless control module (25) configured to transmit wireless control signals associated with operation of the zoom control buttons (23, 24), and the wireless module (15) is configured to receive the wireless control signals from the wireless control module (25) and to perform, zoom control of the camera modules (12) according to the wireless control signals. ~

6. The laparoscopic camera system of claim 4, wherein the handle device (20) further includes a rechargeable power module having a power button (26) and a charging port (27) both disposed at the device body (21), the power button (26) being operable to turn on and turn off the handle device (20).

7. The laparoscopic camera system of claim 4, wherein the handle device (20) further includes at least one strap (28, 29) provided on the device body (21) to secure the hand of the user on the device body (21).

8. The laparoscopic camera system of claim 1, further comprising a port device (30) that includes a camera port component (31) and a sleeve connector component (32); wherein the camera port component (31) includes a cylindrical port body (310), a top valve part (311) located at a top end of the cylindrical port body (310) to serve as a passageway for the camera device (10) into the abdominal cavity, multiple instrument ports (312) distributed on the cylindrical port body (310) for passage of laparoscopic instruments, a push-vent (313) located on the cylindrical port body (310) and operable to release cauterization smoke from the abdominal cavity, and an insufflation port (314) located on the cylindrical port body (310) to serve as a passageway for insufflating air; and wherein the sleeve connector component (32) includes an elastic sleeve body (320) with a top part (321) coupled to a bottom part (315) of the cylindrical port body (310), the elastic sleeve body (320) being configured for insertion through the incision made on the umbilicus down to the peritoneum.

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9. The laparoscopic camera system of claim 1, further comprising a placement device (40) that : includes: } oo o a handle (41); | > a placement shaft (42) connected to the handle (41) and having a bendable joint (43); = oo a first knob (44) provided on the handle (41) and operable to bend the placement shaft (42) at the bendable joint (43); , : a loop component (45) coupled to the placement shaft (42); and a second knob (46) provided on the handle (41) and operable to tighten the loop component (45) on the camera device (10) or loosen the loop component (45) from the camera device (10).

10. The laparoscopic camera system of claim 9, wherein the placement shaft (42) is connected removably to the handle (41), the placement device (40) further including a retrieval shaft (47) connected removably to the handle (41), and a pouch component (48) coupled to the retrieval shaft (47) and configured for retrieving the camera device (10) from the patient’s abdomen. LC | 1