The present disclosure relates generally to devices used to clean both the trocar and the lens of a scope used in minimally invasive surgery. The present disclosure also relates to methods of cleaning both the trocar and the lens of a scope used in minimally invasive surgery by inserting a rod through the trocar and the foam end conforms to the inner cannula of the trocar.
The number of minimally invasive, robotic, and endoscopic procedures continue to increase since these types of procedures allow patients to heal faster with a shorter recovery time and a decreased risk for wound infections and hernias. These procedures entail small incisions to introduce instruments and scopes into various body cavities to perform a wide range of medical procedures that include ligating, cutting, suturing, and repairing tissue. However, these techniques require a continuous and clear image during the entire procedure. Typically, cannulas, trocars, or ports are placed through the small incisions and serve as portals to various body cavities. Due to the breadth of procedures, trocars are made of varying materials that range in length and diameter from one manufacturer to another.
Once the scope is inserted through a trocar, the scope lens may become obstructed due to smudging, condensation, or direct contact with pieces of tissue, bodily fluids, and condensation. These fluids include blood, bile, and fecal material. Also, pieces of tissue and fluid may be trapped within the trocars and collect on the lens as the scope is inserted into the body. Unfortunately, the field of view may be compromised numerous times during a procedure and prolong or hinder the progress of the procedure.
In order to provide the surgeon with a clear view, the scope needs to be removed from the body cavity, cleaned, and reinserted. During some procedures, it is not uncommon to remove and clean the scope 10-20 times which substantially increases the duration of the procedure and potentially leads to other complications. Thus, there is a need for a device that cleans the lens of the scope while the scope remains in a body cavity. As well, the device should concurrently clean the entire length of the trocar to ensure that tissue and fluid do not collect on the scope lens as it is inserted into the body.
The disclosed device and methods are directed to one or more of the problems set forth above and/or other problems of the prior art.
In accordance with one aspect of the technology, a method is provided of cleaning trocars or cannulas and a lens of a scope by using a minimally invasive device including a rod having at least one sponge attached to an end thereof. The method can include inserting one end of the device through a trocar such that the at least one sponge is in contact with an inner surface of the trocar to thereby clean the inner surface of the trocar. The device can be extended through the trocar such that the sponge is positioned within a body cavity. The sponge can be used to clean the lens of the scope while the scope and the sponge are within the body cavity.
The following drawings illustrate exemplary embodiments for carrying out the invention. Like reference numerals refer to like parts in different views or embodiments of the present invention in the drawings.
As used herein, “minimally invasive” refers to a surgical procedure that is performed through tiny incisions instead of one large opening. During a typical minimally invasive procedure, surgeons make several small incisions in the skin, on the order of a few millimeters, in some cases. There are described devices used in such procedures that can pass through one of the incisions. These devices are called trocars or cannulas. The trocars act as a portal to the body cavity as they traverse into the body cavity.
There are disclosed herein devices used to clean both the trocar and the lens of a scope used in minimally invasive surgery. In an embodiment, the device comprises a rod with foam or sponges that may be attached to both ends. The cleaning segments can include, for example, foam or sponges or various components combined into sponge assemblies. The two-headed device can clean a variety of trocar sizes and various scopes. In an embodiment, the minimally invasive device described herein concurrently cleans trocars or cannulas and the lens of the scope.
There is also disclosed a method of cleaning trocars or cannulas of a scope concurrently with the lens of a scope by using the minimally invasive device described herein. In an embodiment, the method comprises cleaning both the trocar and the lens of a scope used in minimally invasive surgery by inserting a rod through the trocar and the foam end conforms to the inner cannula of the trocar. The rod is gently slid through the trocar and debris or fluid is pushed out of the trocar or absorbed by the sponge. Concurrently, the foam end may be used to clean the lens of the scope while the scope is still in the body cavity. Different shapes of foam with varying lengths and diameters are available for both ends of the rod. This variety maximizes the utility of the two-headed rod.
In one embodiment, the method may comprise attaching a first sponge to the rod, inserting one end of the device through the trocar such that at least one sponge is in contact with the inner surface of the trocar. Once the device is engaged within the trocar, the rod is grasped and used to clean the inner cannula. The device is removed after sufficient cleaning is performed. The scope may then be reinserted through the trocar. If debris or fluid is still within the trocar, the cleaning procedure is repeated. If the lens becomes dirty, the rod with the attached sponge may also be used to enter another trocar and clean the lens of the minimally invasive scope without removing the scope from the body cavity. The detachable sponges may be exchanged multiple times during the procedure if the sponge becomes dirty or damaged. The sponges are detachable and new sponges may be exchanged multiple times during the procedure.
A device is described to clean a wide range of trocars regardless of diameter or length. The device includes a rod with two variegated ends. Sponges or a variety of foam shaped structures may be attached and detached to the ends of the rod. These sponges are available in various lengths, widths, and shapes to accommodate a wide range of minimally invasive and robotic trocars and procedures. Once the device is inserted through the trocar, the sponges can be used to clean the scope lens.
Numerous types of sponges may be attached and detached to the rod as needed to ensure that the trocar and lens remain clean during the entire surgical procedure. The scope and trocar cleaning device may consist of a rod with a sponge or foam connected to each end. The figures and text describe the rod and sponge in more detail. The varying degree of sizes and types of sponges allow the device to clean a wide range of trocars while exchanging the foam ends during the procedure if the sponge becomes dirty. Numerous manufacturing companies make a variety of different trocars with varying diameters. Different size sponges may be attached to the rod to accommodate the various trocars. Regardless of size, the same sponge may be used to clean the scope lens.
The rod may be made of a hard plastic, silicone, stainless steel, or various alloys. The rod may be used as a disposable or a reusable device depending on the type of material. In one embodiment, the length of the rod should extend 10 cm, at a minimum. As well, rods may extend over 50 cm for longer trocars.
The rod may have a circular circumference but may also have a hexagonal circumference to enhance tactile feedback and twirling of the device to clean the trocar and lens. Alternatively, various external circumferences or shapes of the rod may be used to augment twirling of the rod as it is inserted and manipulated.
The ends of the rod may include threads, clips, hooks, or variegated edges that facilitate a wide range of sponge attachments. As shown in
With further reference to
In other embodiments, the strip may be embedded within the sponge. In other embodiments, the strip may be formed from radiopaque markings or dyes applied to the sponge. Additional strips may be provided to allow the surgeon to enhance visualization of lens cleaner through X-ray, fluoroscopy, MRI, and/or CT scan imaging.
In various embodiments, the sponge may be made of foam, cotton, or an absorptive material that can gently clean the lens of a scope. The material should be sturdy enough to clean the inside of the trocar. The sponge may be manufactured into various shapes such as a cylinder, sphere, hexagon, or ellipse to enhance trocar cleaning.
The length and diameter of the sponge includes a range of sizes to accommodate various trocar diameters and lengths. In one embodiment, the sponge is at least 1 cm in length and may extend to 4 cm in length. The diameter of the sponge may range from 2 mm to 50 mm, such as from 5 mm to 40 mm, 10 mm to 30 mm, or 15 to 25 mm. Since the rod entails two ends, two different or two similar sizes of sponge may be attached to each respective end of the rod.
The sponge material can compress as it is inserted through a cannula or trocar. The sponge material would then expand slightly as it exits the trocar and extends into the body cavity. The trocar tip and undersurface of the trocar tip are cleansed as the sponge expands when it exits the trocar and enters the body cavity.
The sponges may have corresponding adaptive couplers, threads, or cored inlets to attach seamlessly to the ends of the rod. The rod may extend into the center of the sponge or entirely through the sponge to ensure adequate support and structural integrity. As shown in
An X-ray detectable strip is embedded or wrapped around the sponge. This strip may help locate the sponge if it becomes detached in the body. The strip may be a piece thread, wire, or sheet of X-ray detectable material.
An exemplary method may be disclosed herein. During an exemplary minimally invasive procedure, the lens of the scope inevitably becomes smudged or dirty and obscures the surgeon's view. The scope does not need to be removed from its respective trocar. The two-headed rod is used through a second trocar. The diameter and length of the second trocar is grossly measured and a corresponding sponge is attached to the rod. Two slightly different sponges or similar sponges may be used depending on the trocar or type of debris or fluid on the lens. The unique ability of this device allows the scope lens to be cleaned without removing the scope from the body cavity.
During an exemplary minimally invasive procedure, the device is inserted through a second trocar while the scope remains in the body. The sponge on one end of the rod is inserted through the trocar and directed towards the lens of the scope. Simultaneously, the scope can visualize the device as it enters the body cavity through the tip of the trocar. The scope is held in place but is directed towards the sponge. The sponge is then used to wipe the lens gently to remove fluid, tissue, or condensation from the lens. This action may be repeated multiple times to obtain a clear field of vision.
Alternatively, the rod and corresponding sponge may be held steady and the scope may be advanced slowly towards the sponge. The scope may then be wiped gently against a stationary sponge to clear any debris from the field of vision. The entire device may be removed from the second trocar and flipped 180 degrees along its long axis and the sponge at the opposite end of the rod may be used in a similar fashion to clean the lens of the scope. As well, the entire device may be removed from the trocar and the sponge may be removed and replaced with a clean sponge or a sponge with a different shape or contour. The capacity to remove and add new sponges enables the device to continual clean a dirty or smudged lens.
If debris or fluid accumulates within the trocar, the device may be used to clean the inner tunnel of the trocar. The sponge at the tip of the rod is inserted through the center of the trocar and slowly introduced through the entire length of the trocar. The rod may be twirled or twisted as the sponge is inserted to ensure that the entire tract of the trocar is cleaned. The sponge is then removed from the trocar and the scope may be introduced through the clean inner tunnel of the trocar. If the trocar still contains tissue or fluid, the sponge may be reinserted. If the sponge is dirty, then the opposite end of the device may be inserted. Alternatively, the sponge may be detached and a new clean sponge may be attached to the end of the rod.
As depicted herein, the unique capacity of this device embodies both a trocar cleaning device and a device to simultaneously clean a scope lens during a minimally invasive or robotic procedure. The method of cleaning may be performed during any surgery involving a scope. For example, the method may be applicable to procedures performed laparoscopically, thoracoscopically, endoscopically, and robotically.
Other types of cleaning devices that might be in combination with the disclosed device are described in U.S. Pat. No. 10,114,216 (U.S. Published Appl. No. 2016/0022367), which is herein incorporated by reference. The device described in this comprises a sleeve including an inner surface configured to engage a medical device; and a pad secured around the sleeve and configured to wipe the lens of the scope.
It will be appreciated that the foregoing description provides examples of the disclosed system and technique. However, it is contemplated that other implementations of the disclosure may differ in detail from the foregoing examples. All references to the disclosure or examples thereof are intended to reference the particular example being discussed at that point and are not intended to imply any limitation as to the scope of the disclosure more generally. All language of distinction and disparagement with respect to certain features is intended to indicate a lack of preference for the features of interest, but not to exclude such from the scope of the disclosure entirely unless otherwise specifically indicated.
Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context.
This application is a divisional of copending U.S. patent application Ser. No. 15/418,022, filed Jan. 27, 2017, which claims priority to U.S. Provisional Application Ser. No. 62/288,143, filed on Jan. 28, 2016, each of which is hereby incorporated herein by reference in its entirety.
Number | Date | Country | |
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62288143 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 15418022 | Jan 2017 | US |
Child | 16573616 | US |