阅读说明：本技术 具有释放特征的手术进入组件 (Surgical access assembly with release feature ) 是由 凯文·德雅尔丹 阿什利·C·罗伯 道格拉斯·M·帕蒂森 克里斯托弗·A·托卡扎 雅各布·C· 于 2021-06-02 设计创作，主要内容包括：本公开涉及具有释放特征的手术进入组件,并提供一种手术进入组件,其包含手术进入装置,所述手术进入装置具有套管、位于所述套管的远侧区域中的可扩张球囊以及位于所述套管的近侧区域中的膨胀组件。所述膨胀组件具有端口和止回阀。所述端口与所述可扩张球囊进行流体连通,且所述止回阀可在静止配置与致动配置之间转变。注射器包含具有腔室的针筒和可滑动地设置在所述腔室中的柱塞。所述针筒的延伸部被配置成可释放地接合所述止回阀。所述柱塞还包含释放特征,所述释放特征可与所述止回阀接合以使所述止回阀从所述静止配置转变到所述致动配置。(The present disclosure relates to a surgical access assembly having a release feature and provides a surgical access assembly including a surgical access device having a cannula, an expandable balloon located in a distal region of the cannula, and an inflation assembly located in a proximal region of the cannula. The expansion assembly has a port and a check valve. The port is in fluid communication with the expandable balloon, and the check valve is transitionable between a resting configuration and an actuated configuration. The syringe includes a barrel having a chamber and a plunger slidably disposed in the chamber. The extension of the syringe is configured to releasably engage the check valve. The plunger also includes a release feature engageable with the check valve to transition the check valve from the rest configuration to the actuated configuration.)

1. A surgical access assembly, comprising:

a surgical access device comprising

The casing pipe is provided with a plurality of casing pipes,

an expandable balloon located in a distal region of the cannula, an

An inflation assembly located in a proximal region of the cannula, the inflation assembly including a port in fluid communication with the expandable balloon and a check valve transitionable between a resting configuration that allows fluid flow in a first direction and inhibits fluid flow in a second direction opposite the first direction and an actuated configuration that allows fluid flow in the first and second directions; and

a syringe comprising

A syringe having proximal and distal openings defining a chamber therebetween, the chamber configured to store an inflation fluid therein,

an extension configured to releasably engage a portion of the check valve,

a plunger slidably received in the chamber through the proximal opening and configured to expel at least a portion of the inflation fluid stored in the chamber through the distal opening, an

A release feature engageable with the check valve to transition the check valve from the rest configuration to the actuated configuration.

2. The surgical access assembly of claim 1, wherein the release feature is insertable into the port to transition the check valve from the resting configuration to the actuated configuration.

3. The surgical access assembly of claim 1, further including the distal opening of the syringe engaged with the port such that translation of the plunger into the chamber delivers inflation fluid through the port transitioning the check valve from the rest configuration to the actuated configuration.

4. The surgical access assembly of claim 2, wherein the release feature is a protrusion on a distal end of the plunger.

5. The surgical access assembly of claim 3, wherein the expandable balloon transitions from a collapsed configuration to an expanded configuration as the plunger is translated distally through the chamber.

6. The surgical access assembly of claim 4, wherein the check valve includes a piston and a spring that biases the piston proximally toward the port.

7. The surgical access assembly of claim 6, wherein the protrusion is engageable with a portion of the piston and adapted to translate the piston distally, thereby transitioning the check valve from the rest configuration to the actuated configuration.

8. A method of accessing a surgical site, comprising:

inserting a portion of a surgical access device into a patient, the surgical access device comprising a cannula, an expandable balloon disposed in a distal region of the cannula, and an inflation assembly disposed in a proximal region of the cannula;

coupling a syringe to the inflation assembly such that a distal opening of a syringe of the syringe is located in a port of the inflation assembly;

translating a plunger in a chamber of the syringe, thereby pressurizing inflation fluid in the chamber and transitioning a check valve of the inflation assembly from a resting configuration to an actuated configuration such that the chamber is in fluid communication with the expandable balloon; and

transitioning the expandable balloon from a collapsed configuration to an expanded configuration by continuing translation of the plunger toward a distal region of the chamber such that the check valve remains in the actuated configuration and inflation fluid is communicated from the chamber to the expandable balloon.

9. The method of claim 8, further comprising:

decoupling the syringe from the inflation assembly;

inserting a surgical instrument through the cannula; and

performing a surgical procedure at the surgical site.

10. The method of claim 9, further comprising inserting a protrusion of the plunger into the port, thereby transitioning the check valve from the resting configuration to the actuated configuration.

11. The method of claim 10, further comprising:

removing the surgical access device from the patient; and

transitioning the expandable balloon from the expanded configuration to the collapsed configuration by venting the inflation fluid through the check valve and the port.

12. The method of claim 8, further comprising decoupling the syringe from the expansion assembly.

13. The method of claim 12, further comprising inserting a protrusion of the plunger into the port, thereby transitioning the check valve from the resting configuration to the actuated configuration.

Technical Field

The present disclosure generally relates to a surgical access assembly. In particular, the present disclosure relates to a surgical access assembly having a release feature for actuating a check valve of a surgical access device.

Background

Surgical access devices allow for the introduction of various surgical instruments into a body cavity or opening during minimally invasive procedures, including endoscopic and laparoscopic procedures. A surgical access device (e.g., a cannula or access port) is introduced through an opening (e.g., a naturally occurring orifice or incision) in tissue to access an underlying surgical site within the body. The opening is typically formed using an obturator having a blunt or sharp tip that may be inserted through the passageway of the surgical access device. For example, the casing has a rigid material tube with a thin-walled construction through which the obturator can pass. An obturator is used to penetrate the body wall, such as the abdominal wall, or introduce a surgical access device through the body wall, and is then removed to permit introduction of surgical instruments through the surgical access device to perform a minimally invasive surgical procedure.

Minimally invasive surgical procedures, including endoscopic and laparoscopic procedures, allow for surgery to be performed on organs, tissues, and vessels removed from an opening in tissue. In laparoscopic surgery, for example, CO₂Insufflating gas insufflates the abdominal cavity to create a pneumoperitoneum, thereby providing access to the underlying organs. Laparoscopic instruments are introduced into the abdominal cavity through the cannula to perform one or more surgical tasks. The cannula may incorporate a seal to establish a substantially fluid tight seal around the laparoscopic instrument to maintain pneumoperitoneum integrity. Cannulas subjected to a pressurized environment, such as pneumoperitoneum, may contain anchors to prevent withdrawal of the cannula from an opening in the abdominal wall, such as when a laparoscopic instrument is withdrawn from the cannula.

Disclosure of Invention

A surgical access assembly includes a surgical access device having a cannula, an expandable balloon located in a distal region of the cannula, and an inflation assembly located in a proximal region of the cannula. The expansion assembly includes a port and a check valve. The port is in fluid communication with the expandable balloon, and the check valve is transitionable between a resting configuration and an actuated configuration. The stationary configuration allows fluid flow in a first direction and inhibits fluid flow in a second direction opposite the first direction. The actuation arrangement allows fluid flow in first and second directions. The surgical access assembly also includes an injector having a barrel with proximal and distal openings defining a chamber therebetween configured to store an inflation fluid therein. The extension of the syringe is configured to releasably engage a portion of the check valve. The syringe also has a plunger slidably received in the chamber through the proximal opening and configured to expel at least a portion of the inflation fluid stored in the chamber through the distal opening. The plunger also includes a release feature engageable with the check valve to transition the check valve from the rest configuration to the actuated configuration.

In aspects, a release feature may be inserted into the port to transition the check valve from the resting configuration to the actuated configuration.

In an aspect, a distal opening of the syringe may be engaged with the port such that translation of the plunger into the chamber delivers inflation fluid through the port, transitioning the check valve from the rest configuration to the actuated configuration.

In another aspect, the release feature may be a protrusion on the distal end of the plunger.

In an aspect, the expandable balloon may transition from the collapsed configuration to the expanded configuration as the plunger is translated distally through the chamber.

In various aspects, the check valve may include a piston and a spring that biases the piston proximally toward the port.

In an aspect, the protrusion is engageable with a portion of the piston and adapted to translate the piston distally to transition the check valve from the rest configuration to the actuated configuration.

A method of accessing a surgical site includes inserting a portion of a surgical access device into a patient. The surgical access device includes a cannula, an expandable balloon disposed in a distal region of the cannula, and an inflation assembly disposed in a proximal region of the cannula. The method further includes coupling the injector to the inflation assembly such that a distal opening of the syringe of the injector is located in a port of the inflation assembly. Additionally, the method includes translating a plunger in a chamber of the syringe, thereby pressurizing inflation fluid in the chamber and transitioning a check valve of an inflation assembly from a resting configuration to an actuated configuration such that the chamber is in fluid communication with the expandable balloon. Further, the method includes transitioning the expandable balloon from the collapsed configuration to the expanded configuration by continuing translation of the plunger toward the distal region of the chamber such that the check valve remains in the actuated configuration and inflation fluid is communicated from the chamber to the expandable balloon.

In one aspect, the method may include decoupling the syringe from the inflation assembly, inserting a surgical instrument through the cannula, and performing a surgical procedure at the surgical site.

In another aspect, the method may include inserting a protrusion of a plunger into a port, thereby transitioning a check valve from a resting configuration to an actuated configuration.

In various aspects, the method may include removing the surgical access device from within the patient and transitioning the expandable balloon from the expanded configuration to the collapsed configuration by venting inflation fluid through the check valve and the port.

Other features of the present disclosure will be understood from the following description.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate aspects and features of the disclosure and, together with the detailed description below, serve to further explain the disclosure in which:

FIG. 1 is a perspective view of a surgical access assembly having a surgical access device and a syringe;

FIG. 2 is a perspective view of the syringe of FIG. 1;

FIG. 3 is an exploded perspective view of the syringe of FIG. 2 with parts separated;

FIG. 4 is a side cross-sectional view of the surgical access assembly of FIG. 1 taken along section line 4-4;

FIG. 4A is a cross-sectional view of the surgical access assembly of FIG. 1 taken along section line 4A-4A;

FIG. 5 is an enlarged view of the detail area of FIG. 4 showing the check valve in an actuated configuration;

FIG. 6 is an enlarged view of FIG. 5 showing the check valve in a resting configuration;

FIG. 7 is a perspective view of the surgical access assembly of FIG. 1 with a plunger of a syringe coupled to an inflation assembly of the surgical access device;

FIG. 8 is a side cross-sectional view of the surgical access assembly of FIG. 7, taken along section line 8-8, and partially inserted into tissue;

FIG. 9 is an enlarged view of the detail area of FIG. 8 showing the engagement between the check valve and the release feature; and

fig. 10 is a side cross-sectional view of the surgical access assembly of fig. 8 removed from tissue.

Detailed Description

Aspects of the present disclosure are described below with reference to the drawings; however, it is to be understood that the disclosed aspects are merely exemplary of the disclosure and may be embodied in various forms. Well-known functions or configurations are not described in detail to avoid obscuring the present disclosure in unnecessary detail. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present disclosure in virtually any appropriately detailed structure.

The description of technical features of one aspect of the present disclosure should generally be considered available and applicable to other similar features of another aspect of the present disclosure. Accordingly, technical features described herein according to one aspect of the present disclosure may be applicable to other aspects of the present disclosure, and thus, a repetitive description may be omitted herein. Like reference numerals may refer to like elements throughout the specification and drawings.

Referring initially to fig. 1, a surgical access assembly of the present disclosure is shown and identified as surgical access assembly 10. Surgical access assembly 10 includes a surgical access device 100 and a syringe 200. Surgical access device 100 has a housing 110 at its proximal end. The housing 110 has an opening 112 that allows insertion of a hand therethroughSurgical instrument "I" (fig. 4). Thus, the clinician is able to perform a surgical procedure at the surgical work site below the surface tissue "T" (fig. 4). Examples of surgical instruments include, but are not limited to, graspers, staplers, endoscopes, and the like. The housing 110 contains one or more seals (e.g., instrument seals, zero closure seals) that inhibit proximal fluid flow through the housing in the absence of a surgical instrument "I". Additionally, the housing 110 contains a blow-in valve 114. Insufflation valve 114 has a valve handle 116 and an insufflation port 118. The valve handle 116 is rotatable between an open position and a closed position. The insufflation port 118 may be attached to an insufflation fluid (e.g., CO)₂) (not shown) for insufflation of the body cavity to separate layers of bodily tissue and create a working site.

With additional reference to fig. 4 and 4A, the surgical access device 100 also includes an expansion member 120 disposed in a proximal region of the surgical access device 100 and distal to the housing 110. The expansion assembly 120 includes a check valve 130 and a port 122. The port 122 and check valve 130 of the inflation assembly 120 are in fluid communication with an expandable balloon 150 of the surgical access device 100. A sleeve 160 extends distally from the housing 110 and supports the expandable balloon 150 in a distal region thereof. The expandable balloon 150 is fluidly coupled to the inflation assembly 120 via a channel 166 formed along the cannula 160. The channel 166 allows inflation fluid (e.g., air) to be communicated between the inflation assembly 120 and the expandable balloon 150. The cannula includes a lumen 162 extending therethrough that coincides with the opening 112 of the housing 110. Ring 164 is slidably disposed on sleeve 160. Unless the clinician moves the ring 164 along the cannula 160, the ring 164 frictionally maintains its position along the outer surface of the cannula 160 and resists movement along the cannula 160. When the expandable balloon 150 is in the expanded configuration, the loops 164 serve to help maintain the position of the surgical access device 100 in the body tissue by capturing tissue between the loops 164 and the expandable balloon 150.

Referring now to fig. 2-4, the injector 200 includes a syringe 210 and a plunger 220. The barrel 210 has a proximal opening 212 and a distal opening 214 defining a chamber 216 therebetween. Chamber 216 is configured to slidably receive plunger 220 therein. The distal opening 214 is located at the distal end of an extension 218 of the syringe 210. The outer diameter of the extension 218 is smaller than the outer diameter of the syringe 210. In addition, a shield 213 surrounds the extension 218, wherein the diameter of the shield is greater than the diameter of the extension 218 and less than the diameter of the syringe 210. This arrangement between the shield 213 and the extension 218 defines a cavity 215 that facilitates coupling the syringe 200 with the inflation assembly 120 of the surgical access device 100. At the proximal end of the barrel are wings 217 configured to assist the clinician in grasping and manipulating the syringe 200. Plunger 220 has a proximal disc 222 configured to be engaged by a clinician's finger or thumb. The body of the plunger 220 has an X-shaped cross-sectional configuration along a majority of its length defined by ribs 224 having a cylindrical section 226 at its distal end. A protrusion or prong 228 extends distally from the cylindrical section 226 and is configured for engaging the check valve 130, as will be described in detail below. When assembled, the cylindrical section 226 of the plunger 220 is inserted into the chamber 216 through the proximal opening 212. The plunger 220 forms a fluid-tight seal between the outer surface of the cylindrical section 226 and the inner surface of the chamber 216, and a fluid-tight seal between the outer surface of the rib 224 and the inner surface of the chamber 216. As plunger 220 translates distally through chamber 216, air disposed in the chamber is pressurized and expelled through distal opening 214.

Referring now to fig. 4-6, the interaction between the check valve 130 and the syringe 200 will be more fully described. A check valve 130 is located in the passage 124 of the expansion assembly 120 and extends through the port 122. The check valve 130 has a body 132 with a proximal portion 134 and a distal portion 136. The outer diameter of the proximal portion 134 is smaller than the outer diameter of the distal portion 136. The edge 135 separates the proximal and distal portions 134, 136 and helps to secure the check valve 130 in the passage 124 of the inflation assembly 120. The diameter of the rim 135 is greater than the outer diameter of the proximal and distal portions 134, 136. A proximal disk 138 having an aperture 139 is located in proximal portion 134 and is longitudinally spaced from edge 135. The aperture 139 is configured to slidably receive a proximal catch 140 of a plunger 142. The piston 142 may slide within a cavity 144 of the check valve 130. The piston 142 includes a distally extending rod 147, and a portion of the rod 147 extends through an aperture 145 of a distal disc 146 disposed at a distal end of the distal portion 136. Spring 148 surrounds rod 147 and is in contact with distal disc 146 and flange 143 of piston 142. Spring 148 biases piston 142 in the direction of arrow "C" toward port 122, pressing flange 143 against the shoulder between proximal portion 134 and distal portion 136. This defines a rest or closed configuration of the check valve 130 and inhibits fluid flow proximally toward the port 122 (fig. 6). The extension 218 of the syringe 200 may be inserted into the proximal portion 134 of the check valve 130. As plunger 220 translates distally through chamber 216 of syringe 200, inflation fluid (e.g., air) present in chamber 216 is pressurized and forced through extension 218 and out distal tip 214. The inflation fluid travels through the aperture 137 of the proximal disc 138 and contacts the proximal surface of the rim 135 and generates a distally applied force. The distally applied force of the inflation fluid overcomes the bias of spring 148 and pushes piston 142 distally in the direction of arrow "B" so that the inflation fluid may flow through check valve 130 as indicated by arrow "a". The inflation fluid travels through the body 132 of the check valve 130 and exits the distal end of the check valve through the aperture 133 in the distal disc 146. This arrangement defines the actuation configuration of the check valve 130. After passing through the check valve 130, the inflation fluid travels through the channel 166 (fig. 4A) and into the expandable balloon 150. In summary, when the pressure of the inflation fluid at the port 122 is less than the biasing force of the spring 148, the spring 148 urges the piston 142 toward the port and closes the check valve 130 (i.e., the resting configuration). When the pressure of the inflation fluid at port 122 is greater than the biasing force of spring 148, the pressurized inflation fluid pushes piston 142 distally away from port 122, allowing the inflation fluid to travel through check valve 130 (i.e., the actuated configuration) and ultimately to expandable balloon 150.

When inflation fluid is introduced into the expandable balloon 150, the expandable balloon 150 transitions from the deflated state to the inflated state. If the volume of inflation fluid in syringe 200 is insufficient to expand expandable balloon 150 to the desired size, syringe plunger 220 is withdrawn from chamber 216. This allows air to fill chamber 216 such that inserting plunger 220 into chamber 216 and translating plunger 220 distally delivers an additional amount of air into expandable balloon 150, thereby increasing the size of expandable balloon 150. Even if plunger 220 is removed from syringe 200, inflation fluid already in expandable balloon 150 remains there because check valve 130 is now in its resting configuration. The process of adding the expansion fluid may be repeated as desired. Alternatively, syringe 200 may be separated from inflation assembly 120 and plunger 220 partially retracted in chamber 216, allowing additional air to enter chamber 216 through distal opening 214. Subsequently, the syringe 200 is coupled to the inflation assembly 120 as discussed above, and additional inflation fluid is introduced into the expandable balloon 150 as discussed above.

Referring now to fig. 7-10, removal of the surgical access device 100 from the working site is facilitated by rapidly deflating the expandable balloon 150. After the surgical procedure is completed, the clinician inserts plunger 220 into expansion assembly 120 such that prongs 228 of plunger 220 engage proximal tabs 140 of piston 142. Pressing the plunger 220 into the port 122 of the expansion assembly 120 causes the prong 228 to press against the proximal clasp 140 and overcome the bias of the spring 148. This translates piston 142 distally, transitioning check valve 130 from the resting configuration (fig. 6) to the actuated configuration (fig. 5), which allows inflation fluid to flow from expandable balloon 150 through channel 166, through open check valve 130, and out port 122 of inflation assembly 120. This causes the expandable balloon 150 to transition to its deflated state. Specifically, once the prong 228 of the plunger 220 moves the piston 142 distally in the direction of arrow "B," the check valve 130 is now in the actuated configuration. When the pressure of the inflation fluid in the body 132 is greater than the air pressure surrounding the port 122, the inflation fluid travels through the check valve 130 in the direction of arrow "D" away from the check valve 130. Specifically, the inflation fluid travels through the aperture 133 of the distal disc 146, the body 132 of the check valve 130, and the aperture 137 in the proximal disc 138. In conjunction with releasing the inflation fluid by manually actuating the check valve 130 with the plunger 220, the clinician may withdraw the surgical access device 100 from the work site. As shown in fig. 8, withdrawing surgical access device 100 in the direction of arrow "E" brings expandable balloon 150 into contact with the underside of tissue "T". The combination of continued withdrawal of the surgical access device 100 and venting of inflation fluid through the check valve 130 returns the expandable balloon 150 to its deflated state and facilitates removal of the surgical access device 100 from the work site (fig. 10).

Once the clinician identifies the work site, the clinician inserts cannula 160 (fig. 4) of surgical access device 100 through an opening in tissue "T". With the surgical access device 100 in a desired position, the clinician couples the syringe 200 to the port 122 of the inflation assembly 120 and translates the plunger 220 one or more times through the chamber 216 of the syringe to expand the expandable balloon 150 to a desired size such that the expandable balloon 150 anchors the surgical access device 100 at the work site, thereby preventing expulsion of the surgical access device 100. Once the surgical access device 100 is anchored, the clinician slides the ring 164 distally until it contacts the outer surface of the tissue "T," thereby helping to maintain the position of the surgical access device 100 relative to the opening. After the surgical procedure, the clinician inserts the prongs 228 of the plunger 220 through the ports 122 of the inflation assembly 120, thereby transitioning the check valve 130 from its resting configuration (fig. 6) to its actuated configuration (fig. 9), thereby allowing inflation fluid to escape the expandable balloon 150. At the same time, the clinician withdraws the surgical access device 100 through the tissue "T" such that the expandable balloon 150 contacts the underside of the tissue "T," which accelerates the transition of the expandable balloon 150 to the collapsed state and facilitates easy removal of the surgical access device 100 from the working site.

Those skilled in the art will appreciate that the devices and methods specifically described herein and illustrated in the accompanying drawings are non-limiting. It is contemplated that an element or feature may be combined with another element or feature without departing from the scope of the present disclosure. Likewise, one skilled in the art will appreciate further features and advantages of the disclosure.