POLYMERIC GLOVES HAVING EMBEDDED SURGICAL SUPPORT SYSTEMS AND DISCRETE ELEMENTS
A proximity switch system that includes a self-contained power consuming device and a power source in electrical communication with the power consuming element across a magnetic proximity switch is disclosed. The proximity switch system includes an external magnet removably coupled to the magnetic proximity switch. A method of storing and/or transporting a proximity switch system is also disclosed. The method includes providing the proximity switch system and removably coupling an external magnet to the magnetic proximity switch in a position to prevent the magnetic proximity switch from inadvertently switching on.
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This application is a continuation of U.S. patent application Ser. No. 15/151,151, filed May 10, 2016, which claims priority to U.S. Patent Application No. 62/331,203, filed May 3, 2016, and the '151 application is a continuation-in-part of U.S. patent application Ser. No. 14/988,464, filed Jan. 5, 2016, which is a continuation of U.S. patent application Ser. No. 13/626,771, filed Sep. 25, 2012, now U.S. Pat. No. 9,241,764, which claims priority to U.S. Provisional Patent Application No. 61/539,350, filed Sep. 26, 2011, the entireties of which are incorporated herein by reference.
FIELD OF THE INVENTIONThis invention is directed generally to a method of manufacturing surgical gloves including integral surgical systems for use by a surgeon during surgery.
BACKGROUNDU.S. Pat. Nos. 7,931,648, 7,951,145 and 8,182,479 to Schneider (“Schneider patents”) disclosed surgical systems that include a glove with multiple surgical support systems attached thereto. Such gloves provide a number of advantages over conventional surgical systems where the gloves and surgical support systems (e.g., electrocautery, suction, irrigation, light, etc.) are not integrated. There are a wide variety of techniques useful for manufacturing conventional surgical gloves, which allow for high volume production of surgical gloves that meet stringent regulatory standards. However, these techniques are not sufficient for manufacturing the multi-functional surgical gloves described in the Schneider patents, as they do not allow for the integral inclusion of embedded surgical support systems or other elements at the time of glove formation. Adapting commercial products to include surgical support systems would require post-formation processes that would not be cost effective and could compromise the gloves barrier properties. Therefore, there is a need for improvement in the techniques available in order to make and manufacture the surgical systems described in the Schneider patents in a consistent, commercially reliable and cost-effective manner that will not compromise the surgical glove's material integrity or its ability to meet the required regulatory standards.
SUMMARY OF THE INVENTIONThis invention relates to a method of making polymeric gloves, including surgical gloves or other industrial gloves, that contain embedded functional components. The method of making can include providing a first functional component and providing a former comprising an appendage-shaped portion, where the former comprising a first magnetic positioning system. The method can also include producing a loader former by coupling the first functional component to an outer surface of the former using the first magnetic positioning system; and applying a polymer coating over the appendage-shaped portion of the loaded former to form a glove, where at least a portion of the first functional component is embedded within the glove.
In some embodiments, the first magnetic positioning system includes at least one first magnetic positioning element. In some embodiments, the at least one first magnetic positioning element is embedded within the former. In some embodiments, the former is hollow and the at least one first magnetic positioning element is attached to an interior surface of the former. In some embodiments, the at least one first magnetic positioning element is attached to an exterior surface of the former.
In some embodiments, the applying step includes dipping the loaded former into a pool of coating precursor. In some such embodiments, the applying step comprises stabilizing the coating precursor to form the polymer coating.
In some embodiments, the method also includes applying a coating precursor over the appendage-shaped portion of the former prior to producing the loader former. In some embodiments, the method includes removing the glove from the former by turning the glove inside-out.
In some embodiments, the first functional component is a first surgical system that includes a first surgical instrument and a first switch for controlling the first surgical system, and the glove is a surgical glove. In some such embodiments, the first magnetic positioning system comprises a first surgical instrument positioning element adapted to couple the first surgical instrument to the former and a first switch positioning element adapted to couple the first switch to the former.
In some embodiments, a portion of the first functional component is embedded within the glove and another portion of the first functional component is exposed. In some such embodiments, the first functional component is a first surgical system comprising a first surgical instrument and a first switch for controlling the first surgical system, and the exposed portion comprises a portion of the first surgical instrument, a portion of the first switch, or both.
In some embodiments, the method also includes providing a second functional component, and the former includes a second magnetic positioning system. In some such embodiments, the producing step comprises coupling the second functional component to an outer surface of the former using the second magnetic positioning system.
In some such embodiments, the first magnetic positioning system comprises a first surgical instrument positioning element and a first switch positioning element, and the second magnetic positioning system comprises a second surgical instrument positioning element and a second switch positioning element. In some such embodiments, a portion of the first functional component is embedded within the glove and another portion of the first functional component is exposed, and a portion of the second functional component is embedded within the glove and another portion of the second functional component is exposed. In some such embodiments, the exposed portion of the first functional component is a portion of a first surgical instrument, a portion of a first switch, or both, and the exposed portion of the second functional component comprises a portion of a second surgical instrument, a portion of a second switch, or both.
In some embodiments, the first functional component is a first discrete element. In some embodiments, the first magnetic positioning system comprises at least one first discrete element magnetic positioning element.
In some embodiments, the at least one first discrete element magnetic positioning element is embedded within the former. In some embodiments, the former is hollow and the at least one first magnetic positioning element is attached to an interior surface of the former. In some embodiments, the at least one first discrete element magnetic positioning element is attached to an exterior surface of the former. In some embodiments, the first discrete element is embedded in a distal portion of the glove.
Another embodiment described herein is a method of making a polymeric glove. The method can include providing a first functional component; providing a former comprising an appendage-shaped portion; applying a first coating precursor layer over the appendage-shaped portion of the former to form a first glove layer; loading the first functional component over the first glove layer to produce a loaded former; applying a second coating precursor layer over the appendage-shaped portion of the loaded former to form a second glove layer, and removing the polymeric glove from the former. The first functional component can be selected from a first discrete element and a first component system coupled to a first conduit. The polymeric glove can include the first and second glove layers, and at least a portion of the first functional component can be embedded within the polymeric glove.
In some embodiments, the first glove layer is stabilized prior to the loading step.
In some embodiments, the first glove layer is stabilized after the second coating precursor layer is applied but before the removing step.
In some embodiments, the method includes applying a third coating precursor layer over the appendage-shaped portion of the loaded former, including the second glove layer, to form a third glove layer. In some embodiments, the second glove layer is stabilized prior to applying the third coating precursor layer. In some embodiments, the second glove layer is stabilized after the third coating precursor layer is applied but before the removing step.
In another embodiment, a proximity switch system is described. The proximity switch system can include a self-contained power consuming device, comprising a power source in electrical communication with a power consuming element across a magnetic proximity switch; and an external magnet removably coupled to the magnetic proximity switch. In some embodiments, the external magnet is positioned to prevent the magnetic proximity switch from switching on when the device is not in use. In some embodiments, the power source is a battery.
In some embodiments, the power consuming element is a light source. In some embodiments, the external magnet is coupled to the magnetic proximity switch using tape, the magnetism of an internal magnet contained within the proximity switch, a clip, or a combination thereof.
In yet another embodiment, a method of storing and/or transporting a proximity switch system is described. The method can include providing a self-contained power consuming device, comprising a power source in electrical communication with a power consuming element across a magnetic proximity switch; and removably coupling an external magnet to the magnetic proximity switch in a position to prevent the magnetic proximity switch from inadvertently switching on. In some embodiments, the method includes shipping the self-contained power consuming device to a remote location.
These and other embodiments are described in more detail below.
The accompanying drawings, which are incorporated in and form a part of the specification, illustrate embodiments of the presently disclosed invention and, together with the description, disclose the principles of the invention.
A method of making polymeric gloves with component systems, discrete elements, or both, embedded therein is described. The method can be used to completely or partially embed any of a variety of functional components (e.g., component systems, discrete elements) into a polymeric glove. The method of making polymeric gloves can be used to produce a wide variety of gloves including, but not limited to, surgical gloves, cleaning gloves, industrial gloves, and prophylactics. As used herein, “glove” is intended to have its conventional meaning and also include condoms, which can be made using the techniques described herein. Similarly, “appendage-shaped” is intended to include both hand-shaped and phallus-shaped objects.
As shown in the Figures, a method of making a polymeric glove can include providing a first functional component. The first functional component can be selected from a first discrete element and a first component system coupled to a first conduit. The method can also include providing a former comprising an appendage-shaped portion, where the former includes a first depression for receiving the first functional component. The method can include loading the first functional component into the first depression, and applying a polymer coating over the loaded former to form a polymeric glove. As described with respect to surgical gloves below, depending on the desired properties and configuration, the applying step can occur after the loading step or the applying step can occur both before and after the loading step.
As used herein, “functional component” is intended to include both component systems and discrete elements. As used herein, “component systems” include surgical and non-surgical functional components that includes a support conduit for physically connecting to a source (e.g., power source, suction source, irrigation source, etc.) external to the glove. Exemplary component systems include, but are not limited to, light sources 16, cutting sources 18, suction/vacuum sources 20, 554, and irrigation sources 22.
As used herein, “discrete element” refers to a functional component that does not include a conduit for physically connecting to a source external to the glove. Discrete elements must be adapted to functionally enhance the glove and do not include fillers or debris embedded within the material forming the glove. A discrete element could be non-physically connected to an external source, such as via a wireless connection, and could include an internal battery as a power supply. Exemplary discrete elements include, but are not limited to, insulating materials (e.g., heat shield), reinforcing elements, battery operated light sources, temperature strips, reflective elements, resistance thermometers, brushes and other cleaning implements, gripping and friction enhancing elements, and detection strips (e.g., pH, bacteria, toxin, etc.).
The first depression can be adapted to produce an interference fit with at least a portion of a first functional component. A portion of the first functional component can be embedded within the polymeric glove and another portion of the first functional component can be exposed.
The first functional component can be a first discrete element. The first discrete element—and any other discrete element described herein—can be a discrete element selected from the group consisting of insulating materials (e.g., heat shield), reinforcing elements, battery operated light sources, temperature strips, reflective elements, resistance thermometers, brushes and other cleaning implements, gripping and friction enhancing elements, and detection strips (e.g., pH, bacteria, toxin, etc.).
The first functional component can be a first component system comprising a first active end and a first conduit, and the first depression can include a first active end receiving portion and a first conduit receiving portion. In such methods, the loading step can include loading the first active end into the first active end receiving portion and the first conduit into the first conduit receiving portion.
The method can also include providing a second functional component. The second functional component can be selected from a second discrete element and a second component system coupled to a second conduit. The former can include a second depression for receiving a second functional component. The method can include loading the second functional component into the second depression. The first and second function components can be different or the same.
The method can be performed using at least two functional components, at least three functional components, at least four functional components, at least five functional components or more. Any combination of discrete elements and component systems can be used in the method.
As shown in
In such a method, the former 210 can include discrete element receiving portions 410 at the distal, volar portion of the thumb 412 and each of the fingers 414, 416, 418, 420. The discrete element receiving portions 410 at the distal, volar portions of the thumb 412, index finger 414, long finger 416 and ring finger 418, respectively, can each be adapted to receive scrubbing elements 522. Exemplary scrubbing elements 422 include, but are not limited to brushes, raised surfaces, undulating surfaces, and nubbed surfaces. The scrubbing surface 524 of the scrubbing elements 522 may be embedded in or protruding from the resulting glove 510, shown in
The discrete element receiving portion 420 at the distal, volar portion of the little finger can be adapted to receive a detecting element 526, such as, a bacteria tester. The detecting element can be used to test for certain types of bacteria while the user is wearing the glove 512 formed using the former 210. The detection surface 528 can be embedded in or protruding from the glove 512 shown in
As shown in
As shown in
The inner surface 558 of the vacuum cone 554 can be protruding from the glove 552 and free from a coating of the polymer forming the body of the glove 552 (i.e., the inner surface 558 can be exposed). Similarly, the gripping surface 532 of the gripping element 530 can be exposed and/or protruding from the glove 552. As will be understood, when it is desired for a portion of the functional components 554, 530 to have a exposed surface (e.g., 532, 558) the corresponding receiving portions 412, 454 can form an interference fit with the functional components 554, 530.
As a specific application of the method of making polymeric gloves, a method of making surgical gloves with surgical support systems embedded therein is also described. Although the following discussion is directed toward surgical gloves, surgical support systems, and surgical discrete elements, it should be understood that the techniques described herein can be used to embed any type of functional element into any polymeric glove or similar device. It should also be noted that the phrases “support system” and “component system” are used interchangeably herein.
The method can include providing an hand-shaped former 210 with a plurality of depressions, as shown in
Another embodiment described herein is a method of making a polymeric glove. The method can include providing a first functional component; providing a former comprising an appendage-shaped portion; applying a first coating precursor layer over the appendage-shaped portion of the former to form a first glove layer; loading the first functional component over the first glove layer to produce a loaded former; applying a second coating precursor layer over the appendage-shaped portion of the loaded former to form a second glove layer, and removing the polymeric glove from the former. The first functional component can be selected from a first discrete element and a first component system coupled to a first conduit. The polymeric glove can include the first and second glove layers, and at least a portion of the first functional component can be embedded within the polymeric glove.
In some embodiments, the first glove layer is stabilized prior to the loading step. In some embodiments, the first glove layer is stabilized after the second coating precursor layer is applied but before the removing step.
In some embodiments, the method includes applying a third coating precursor layer over the appendage-shaped portion of the loaded former, including the second glove layer, to form a third glove layer. In some embodiments, the second glove layer is stabilized prior to applying the third coating precursor layer. In some embodiments, the second glove layer is stabilized after the third coating precursor layer is applied but before the removing step.
Prior to describing the method in more detail, exemplary gloves that can be made using the method will be described. The method described herein can be used to produce the gloves described in U.S. Pat. Nos. 7,931,648, 7,951,145 and 8,182,479 to Schneider, and U.S. patent application Ser. No. 13/626,733, entitled “Surgical Glove System and Methods of Using the Same,” filed Sep. 25, 2012, the entirety of which is incorporated herein by reference.
As shown in
The surgical systems 14 can also include a first and a second switch (e.g., 48, 56, 58, 62, 64, 70 and 140) attached to the glove 12 for controlling the first and second surgical systems 14, respectively. The first and second switches (e.g., 48, 56, 58, 62, 64, 70 and 140) can be attached to a finger of the glove 12 to which the first and second surgical systems 14 are attached, respectively. The first and second switches (e.g., 48, 56, 58, 62, 64, 70 and 140) can be operable by a thumb of a human hand wearing the glove 12.
The surgical systems 14 can also include (i) a safety switch 140 attached to the glove 12 for controlling the first surgical system 14 so that said first surgical system 14 will not operate unless both said first switch (e.g., 56 or 58) and the safety switch 140 are actuated simultaneously, or (ii) a shunt 142 for controlling fluid flow between said first and second conduits (e.g., 60 and 68). In some cases, the surgical system 14 can include one or more additional surgical systems 14 and can include both a safety switch 140 and a shunt 142.
The surgical system 10 can also include a surgical gown 30 that includes a support system comprising first and second support conduits 34 for coupling to the first and second conduits 15 of the surgical glove 12, respectively. The first and second support conduits 15 can be attached to the first sleeve of the gown 30 and can terminate is support connectors 149.
The first and second surgical systems 14 can include at least one irrigation port 22 and at least one suction port 20, respectively. The surgical system 10 can include a shunt 142 for controlling fluid flow between the irrigation conduit 68 and the suction conduit 60. The shunt 142 can be used to direct the flow of fluid from the irrigation conduit 68 to the suction conduit 60. The shunt 142 can also be used to direct the flow of fluid toward the suction port 22, away from the suction port 22, or both, either simultaneously or alternately. This can be particularly useful for clearing debris, such as tissue, from the suction system (22, 68 & 69).
The shunt 142 can include first and second T-valves 144, 146 in fluid communication with the irrigation conduit 68 and the suction conduit 60, respectively. The first T-valve 144 can be in fluid communication with the second T-valve 146. As shown in
As shown in
The proximity switch can be a latching switch or a non-latching switch. A latching switch will switch-on and stay on once it is actuated by the actuating element 200 even after the actuating element 200 is removed from the general vicinity of the switch. The latching switch will switch-off when the actuating element 200 is again brought close enough to the switch to release the latch. A non-latching proximity switch will remain on when the actuating element 200 is adjacent the switch, but will turn off when the actuating element 200 is no longer proximate to the switch.
As shown in
In some embodiments, the first actuating element 200, the first switch 48, 448, or both comprise a magnet. In some embodiments, the first actuating element 200 comprises a magnet.
In some embodiment, the first surgical support system 17 can be a light source 16. In some embodiments, as shown in
In some embodiments, the light source 16 can be an electroluminescent system. For example, the light source can include an electroluminescent material and electrodes arranged to cause the electroluminescent material to emit visible light by applying an electrical differential across the electroluminescent material. In some embodiments, the electroluminescent material can be sandwiched between layers of the glove. In other embodiments, the electroluminescent material can be applied to an inner or outer surface of the glove. As will be understood, the electroluminescent material can replace any of the light sources (e.g., LEDs) shown and described herein.
During development of the gloves described herein, it was determined that static switches can accidentally be triggered when the self-contained power consuming device 402 is being transported. This issue may be particularly pronounced for latching, static switches, and where, as here, the proximity switch is part of a self-contained power consuming device 402 that is embedded in the glove (i.e., the product must be shipped with the power source 202 connected to the power consuming element 404. It has been determined that this can be prevented using a proximity switch system 600 as described herein.
As shown in
In some embodiments, the power consuming element 404 is a light source 16. In some embodiments, the external magnet 406 is coupled to the magnetic proximity switch 448 using tape, the magnetism of an internal magnet 408 contained within the proximity switch 448, a clip, or a combination thereof.
In yet another embodiment, a method of storing and/or transporting a proximity switch system 600 is described. The method can include providing a self-contained power consuming device 402, comprising a power source 202 in electrical communication with a power consuming element 404 across a magnetic proximity switch 448; and removably coupling an external magnet 406 to the magnetic proximity switch 448 in a position to prevent the magnetic proximity switch 448 from inadvertently switching on. In some embodiments, the method includes shipping the self-contained power consuming device 600 to a remote location.
As shown in
As shown in
As shown in
The electrocautery system can be designed such that the electrocautery device 18 cannot be activated unless both the safety switch 140 and the appropriate switch (56 or 58, respectively) are actuated simultaneously. Because of the positioning of the safety switch 140, activation of the electrocautery device 18 requires two hands and the potential for injury to the patient, the surgeon or other operating room personnel is greatly reduced or eliminated.
As shown in
As shown in
Each of the conduits (42, 52, 60 and 68) can include a terminal interconnect 148 as a proximal end of the conduit. As shown in
Each of the conduits (42, 52, 60 and 68) can traverse a mid-coronal plane of a finger of the surgical glove 12. Similarly, each of the conduits (42, 52, 60 and 68) can follow a linear isometric path along a finger of the glove. This is of great benefit as it allows the manufacture of a snug fitting surgical glove with the conduits embedded therein. If, as in the prior art, the conduits are positioned along volar or dorsal surfaces of the glove, it is not possible to obtain the desired fit without increasing the risk of separation of the conduit from the glove.
Although
As shown in
In addition, discrete element 84 is positioned on a distal, volar portion of the long finger. This discrete element 84 can provide a reinforcing function or can provide an independent function, such as being a resistance thermometer, a reflector, or a temperature strip.
Reflective elements 88, 90 can be positioned proximate the light sources 16. As shown in
It should be noted that, because the discrete elements (e.g., 80, 82, 84, 86, 88 & 90) can be thin, uniform sheets, the discrete elements can be included on any portion of the hand or any of the fingers, including the thumb and/or ring finger, without interfering with the surgeon's ability to manipulate surgical clamps or other surgical devices while wearing the surgical gloves. Alternately, the thumb and/or ring finger of the gloves can be free of both surgical systems and discrete elements.
Having described exemplary surgical gloves that can be made using the method described herein, a method of making surgical gloves such as those shown in
As will be understood, some of the magnetic positioning elements described herein may not be necessary to achieve adequate coupling of the functional component to the former. This can be helpful, particularly in cases where the particular component of the functional component is not magnetic. For example, some of the conduits may be formed of a plastic material, rather than a ferromagnetic metal, while other elements of the functional component may include ferromagnetic metal. In those instances, there would be no need to include magnetic positioning elements to couple with the non-ferromagnetic elements of the functions component.
The former 710 can also include an irrigation system magnetic positioning system 862. As shown in the volar view of
The former 710 can also include a cutting system magnetic positioning system 864. As shown in the volar view of
The former 710 can also include one or more light source system magnetic positioning systems 866, 868. As shown in the dorsal view of
The first light source system magnetic positioning system 866 can start proximate a distal end of a dorsal or distal aspect of the long finger and extend to an ulnar aspects of the long finger. As shown in
Similarly, the second light source system magnetic positioning system 868 can start proximate a distal end of a dorsal or distal aspect of the index finger and extend to an ulnar aspects of the index finger. As shown in
The former 710 can also include one or more discrete element magnetic positioning systems (e.g., 280, 282, 284, 286, 288, 290). As shown in the volar view of
The former 710 can include at least one reinforcing element magnetic positioning element 782, 786. As shown in
The former 710 can include additional discrete element magnetic positioning elements, such as a thermometer strip depression 784. The corresponding thermometer strip can visually indicate temperature for example by color. As shown in
The magnetic positioning elements can be incorporated into the former 710 using a variety of approaches. In some embodiments, as shown in
As used herein, “depression” refers to an indentation for receiving a portion of a surgical system. Depressions—especially those for surgical systems—can include channel portions with generally U-shaped or V-shaped cross-sections having opposing sides that are generally parallel to one another. As used herein, “generally” refers to the general appearance of a cross-section or a minor deviation for a referenced orientation. For example, generally parallel sides deviate from parallel by ≤30°, or ≤20°, or ≤10, or The sides of the depressions 214 described herein can have generally parallel sides where they are designed to form an interference fit with a portion of a surgical system 14. This helps enable the opposing sides of the former to for a liquid tight seal with the sides of the portion of the surgical system 14. It should be observed that where the cross-section is taken through the center of a depression that is circular, elliptical or similarly shaped, the sides of that shape can be considered generally parallel.
The method can include providing a first surgical system 14 comprising a first surgical instrument 17 and a first switch (e.g., 48, 56, 58, 62, 64, 70 & 140) for controlling the first surgical system 14. The method can include providing a former 210 comprising an hand-shaped portion 212. The former 210 can include a first depression 214 for receiving the first surgical system 14. The first depression 214 can be adapted to produce an interference fit with at least a portion of the first surgical system 14. The first surgical system 14 can be loaded into the first depression 214 and a polymer coating can be applied over the loaded former 210 to form a surgical glove 12. In addition to the hand-shaped portion, the former 210 can include a wrist portion and a proximal forearm portion.
The method can also include providing at least one discrete element (e.g., 80, 82, 84, 86) such as, but not limited to, a heat shield, a reinforcing material and a temperature indicating device. The former 210 can include at least one discrete element depression (e.g., 280, 282, 284, 288, 290) for receiving the at least one discrete element (e.g., 80, 82, 84, 86, 88, 90). The at least one discrete element depression (e.g., 280, 282, 284, 286, 288, 290) can be, but is not necessarily, adapted to produce an interference fit with at least a portion of the discrete element (e.g., 80, 82, 84, 86, 88, 90). The at least one discrete element can be loaded into the at least one discrete element depression (e.g., 280, 282, 284, 286, 288, 290) and a polymer coating can be applied over the loaded former 210 to form a surgical glove 12 using the methods described herein.
The applying step can include dipping the loaded former 210 into a pool of coating precursor. The applying step can include dipping the loaded former 210 into a pool of coating precursor more than once. The applying step can include dipping the loaded former 210 into more than one pool of coating precursor. For example, the loaded former 210 can be dipped into a polymer precursor and then into a polymer stabilization pool (e.g., cross-linker, catalyst, initiator, etc.). The method can be continuous. The method can include heating the loaded former 210 prior to dipping in order to facilitate formation of a coating on the loaded former 210.
Forming a layer or coating as described herein can include dipping the loaded or unloaded former into a polymer precursor one or more times.
As used herein, “coating precursor” is intended to include a composition helpful for forming a stabilized coating. Exemplary coating precursors include, but are not limited to, polymer precursors (e.g., monomer solutions), polymer solutions (including, latex dispersion), catalysts, initiators, cross-linkers, coagulants, and mixtures thereof.
As used herein, “interference fit” is intended to refer to a seal that is fluid tight with respect to the coating precursor. In other words, former-side portions of features of a surgical system that form an interference fit with the former 210 will not be coated during the forming process and will be exposed (i.e., uncoated) once the glove 12 is removed from the former 210. In contrast, because the loaded former 210 is dipped in the coating precursor, all other portions of the surgical system 14 will be surrounded by (i.e., embedded within) the glove material.
The first depression 214 can include a first surgical instrument receiving portion 217 and a first switch receiving portion (e.g., 248, 256, 258, 262, 264 & 270). The first surgical system 14 can also include a first conduit 15 and the first depression 214 can also include a first conduit receiving portion 215. The first surgical system 14 can also include a proximal interconnection 148 and the first depression 214 can also include a proximal interconnection receiving portion 348. The interference fit can be formed with a portion of the first surgical instrument 17, a portion of the first switch (e.g., 48, 56, 58, 62, 64, 70 & 140), a portion of the proximal interconnection 148, or a combination thereof. In some formers 210, there will not be an interference fit between the conduit 15 and the first conduit receiving portion 215.
The method can also include removing the surgical glove 12 from the former 210 by turning the surgical glove 12 inside-out. A portion of the first surgical system 14 can be embedded within the surgical glove 12 and a portion of the first surgical system 14 can be exposed (i.e., extend from the surgical glove 12). The exposed portion can include a portion of the first surgical instrument, a portion of the first switch, or both. The exposed portion can correspond to the former-side of the portion of the first surgical system 14 producing an interference fit with the first depression 214.
As will be understood, it may be particularly useful to have particular portions of the surgical system 14 exposed. Portions that can be beneficial to expose include, but are not limited to, surgical instruments 17, switches (e.g., 48, 56, 58, 62, 64, 70 & 140), ports, and terminal interconnections 148. This may be particularly useful for providing access to switches and ports, as well as, for embodiments where the surgical instruments are removable. In such embodiments, the removable portion cab be attached to the glove after the forming process. In some methods, the former 210 may be dipped, fingers first, into the coating precursor pool to a depth such that the terminal interconnections do not contact the pool of coating precursor.
The method can also include providing a second surgical system 14 comprising a second surgical instrument 17 and a second switch (e.g., 48, 56, 58, 62, 64, 70 & 140) for controlling the second surgical system 14. The former 210 can also include a second depression 214 for receiving the second surgical system 14. The second depression 214 can be adapted to produce an interference fit with at least a portion of the second surgical system 14. The second surgical system 14 can be loaded into the second depression 214.
The second depression 214 can include a second surgical instrument receiving portion 217 and a second switch receiving portion 215. The second surgical system 14 can also include a second conduit 15 and the second depression 214 can include a second conduit receiving portion 215. The second surgical system 14 can also include a proximal interconnection 148 and the second depression 214 can include a proximal interconnection receiving portion 348. The interference fit can be formed with a portion of the second surgical instrument 17, a portion of the second switch (e.g., 48, 56, 58, 62, 64, 70 & 140), a portion of the proximal interconnection 148, or a combination thereof. In some formers 210, there will not be an interference fit between the second conduit 15 and the second conduit receiving portion 215.
As will be understood, additional surgical systems 14 and depressions 214 can be included in order to produce any and all embodiments of surgical gloves 12 described herein. For example, the depressions 214 for receiving the surgical systems 14 can be positioned in an index finger, a long finger or a little finger of the former 210. Similarly, as shown in
Depending of the desired configuration, the some or all of the surgical systems 14 and discrete elements (e.g., 80, 82, 84, 86, 88, 90) can be loaded into the respective depressions 214 before or after the former 210 is dipped into the first coating precursor material. Where the surgical system(s) 14 and/or discrete elements (e.g., 80, 82, 84, 86, 88, 90) are loaded into the respective depressions after the former 210 is dipped into the coating precursor material, the former 210 will generally also be dipped into the coating precursor material after the surgical systems 14 and/or discrete elements (e.g., 80, 82, 84, 86, 88, 90) are loaded into the former 210.
When the surgical system(s) 14 and/or discrete elements (e.g., 80, 82, 84, 86, 89, 90) are intended to be completely embedded in the glove, the method may be performed so that the former 210 is dipped both before and after the surgical system(s) 14 is/are loaded into the depressions 214 of the former 210. In such methods, the former 210 may be dipped more than once before the surgical system(s) 14 is/are loaded 210 and more than once after the surgical system(s) 14 is/are loaded into the former 210. For example, the former may be dipped into a polymer precursor (e.g., monomer solutions) or polymer solution (including, latex dispersion) and subsequently dipped into a solution containing one or more of a catalyst, an initiators, a coagulant, and a cross-linker.
An exemplary interference fit for the suction control port 64 is shown in
The former 210 can also include an irrigation system depression 362. As shown in the volar view of
The former 210 can also include a cutting system depression 364. As shown in the volar view of
An exemplary interference fit is shown in
The former 210 can also include one or more light source system depressions 366, 368. As shown in the dorsal view of
The first light source system depression 366 can start proximate a distal end of a dorsal or distal aspect of the long finger and extend to an ulnar aspects of the long finger. As shown in
Similarly, the second light source system depression 368 can start proximate a distal end of a dorsal or distal aspect of the index finger and extend to an ulnar aspects of the index finger. As shown in
The former 210 can also include one or more discrete element depressions (e.g., 280, 282, 284, 286, 288, 290). As shown in the volar view of
The former 210 can include at least one reinforcing element depression 282, 286. As shown in
The former 210 can include additional discrete element depressions, such as a thermometer strip depression 284. The corresponding thermometer strip can visually indicate temperature for example by color. As shown in
As shown in the end view of
The depths and fit of the depressions can be varied in order to leave appropriate portions of the surgical systems 14 exposed after application of the coating and other portions completely embedded in the glove. For example, a loose fit may be desired around the conduits so that they are completely embedded in the polymer forming the glove 12. In contrast, an interference fit between portions of a depression and portions of a surgical system may be utilized in order to have certain portions exposed, e.g., switches, ports and interconnects.
In some methods, the former 210 may be dipped only up to the wrist in order to ensure that the proximal portions of the conduits (e.g., 42, 52, 60 and 68) and the terminal connector 148 are exposed. For example, as shown in
It is known to use formers in the production of elastomeric gloves. These conventional formers are shaped similarly to the human hand and do not include depressions, especially depressions adapted to receive surgical systems and discrete elements such as those described herein. Thus, attachment of surgical systems to conventional elastomeric gloves would require post-formation attachment of the surgical system to the elastomeric gloves, which is inefficient and risks the integrity of the barrier function of the gloves. The claimed method and formers are a significant improvement over the conventional techniques. Accordingly, the invention is also drawn to the formers described herein for use in the methods described herein.
The foregoing is provided for purposes of illustrating, explaining, and describing embodiments of this invention. Modifications and adaptations to these embodiments will be apparent to those skilled in the art and may be made without departing from the scope or spirit of this invention.
Claims
1. A proximity switch system, comprising:
- a self-contained power consuming device, comprising a power source in electrical communication with a power consuming element across a magnetic proximity switch; and
- an external magnet removably coupled to said magnetic proximity switch.
2. The device according to claim 1, wherein said external magnet is positioned to prevent the magnetic proximity switch from switching on when the device is not in use.
3. The device according to claim 1, wherein the power source is a battery.
4. The device according to claim 1, wherein the power consuming element is a light source.
5. The device according to claim 1, wherein the proximity switch is a reed switch.
6. A method of storing and/or transporting a proximity switch system, comprising:
- providing a self-contained power consuming device, comprising a power source in electrical communication with a power consuming element across a magnetic proximity switch; and
- removably coupling an external magnet to said magnetic proximity switch in a position to prevent the magnetic proximity switch from inadvertently switching on.
7. The method of claim 6, further comprising, transporting the self-contained power consuming device to a remote location.
8. The method to claim 6, wherein the proximity switch is a reed switch.
Type: Application
Filed: Jun 21, 2019
Publication Date: Oct 3, 2019
Applicant: (Palm Beach Gardens, FL)
Inventor: Andrew I. SCHNEIDER (Palm Beach Gardens, FL)
Application Number: 16/377,601