Patent Description:
Under various circumstances, a user may have limited or impaired mobility such that ordinary urinary functions and processes are rendered difficult or even impossible. For example, a person may have impaired mobility due to a disability or may be bedridden due to injury or illness. In another example, a person may be subject to restricted occupational conditions under which the person has limited mobility. Finally, urine collection may be needed for monitoring purposes, such as for monitoring inputs and outputs in a clinical setting (e.g. in the ICU, or for other clinical and/or laboratory testing).

Various approaches have been developed to address some of the problems or circumstances related to impaired or restricted urinary processes. However, the prior approaches suffer from problems or limitations of their own. Urinary catheters, for example, can address problems arising from urinary incontinence or limited mobility, but urinary catheters can often be uncomfortable and can contribute to complications (for example, infections). Bed pans, as another example, are containers occasionally used for collecting urinary output of a bedridden person (such as a patient at a health care facility), but bed pans can contribute to patient discomfort, spillage, and issues related to sanitation or hygiene.

<CIT> discloses a system suitable for collecting and transporting urine away from the body of a person or animal may include an assembly having a fluid impermeable casing having a fluid reservoir at a first end, a fluid outlet at a second end, and a longitudinally extending fluid impermeable layer coupled to the fluid reservoir and the fluid outlet and defining a longitudinally elongated opening between the reservoir and the outlet. The assembly further includes a fluid permeable support disposed within the casing with a portion extending across the elongated opening, and a fluid permeable membrane disposed on the support and covering at least the portion of the support that extends across the elongated opening, so that the membrane is supported on the support and disposed across the elongated opening. The assembly further includes a tube having a first end disposed in the reservoir and a second, fluid discharge end.

The figures generally show a device for collecting and removing urine that has been discharged from the body of a user, in particular a female user (e.g., a human female), according to various exemplary embodiments. However, it should be understood that the device described herein may be used with a variety of patients, including male patients with certain anatomical conditions. The device for collecting and removing urine discharged from a user is configured to hold its placement near the pelvic region on a body of a user such that fluid leakage from the device is minimized or eliminated.

Referring to <FIG>, a urine collection device <NUM> according to an exemplary embodiment of the present disclosure is shown. Urine collection device <NUM> includes an external covering <NUM> having an open first end <NUM> and an open second end <NUM>. In an exemplary embodiment, the external covering <NUM> is fluid impermeable. A longitudinally extending fenestration <NUM> is disposed in a portion of the external covering <NUM> between the open first end <NUM> and the open second end <NUM>. In some alternative embodiments, there is more than one fenestration in the external covering <NUM>. The fenestration <NUM> is sized and positioned in the external covering <NUM> to be placed in the area of the patient's urethral opening, such that the fenestration <NUM> allows for fluid flow from an urethral opening of a user's body into a cavity defined by the external covering <NUM> and eventually out to the collection reservoir. In some embodiments, the fenestration <NUM> extends along an entire longitudinal direction of the external covering <NUM>, extending an entire distance from the open first end <NUM> to the open second end <NUM>.

The external covering <NUM> contains and diverts urine that enters through the fenestration <NUM> into a cap <NUM>. From the cap <NUM>, the urine is drawn into a tube <NUM> for removing the urine from the device <NUM>. The external covering <NUM> is configured to hold the interior components of the urine collection device <NUM> together. The external covering <NUM> can be formed from a soft, skin-safe, and hydrophobic material such as silicone, polyurethane, or some other polymeric material in the form of a foam, coating, or a medical grade tape. In some embodiments, an outer surface of the external covering <NUM> is treated with or includes in its material a texture that grips the skin, which may provide greater stability for the device <NUM> to maintain its position.

In the embodiment depicted in <FIG>, the external covering <NUM> takes on a curved, hollowed-out, three-dimensional obround shape which completely envelops one or more fluid collection layers, except for portions that are exposed through the fenestration <NUM>.

In other embodiments, the external covering <NUM> has an alternative shape, such as that depicted in <FIG>. Referring to <FIG>, the external covering <NUM> has a first portion 20a configured to fit over the pubic region of the body of a user, a second portion 20b configured to fit the contours of the perineum of the body of a user, and a third portion 20c configured to cover the coccyx of a user. In one embodiment, the external covering <NUM> has a hydrophobic, closed-cell foam surface having channels that include a hydrophilic material. In other embodiments, the external covering is manufactured of a soft, hydrophobic material (e.g., silicone, polyurethane or other polymeric material) forming a foam or medical-grade tape. In some embodiments, a width of the first portion 20a and a width of the third portion 20c are approximately equal and a width of the second portion 20b is less than the widths of the first and third portions 20a and 20c, respectively.

Referring back to the urine collection device of <FIG>, and particularly to the exploded view of <FIG>, the external covering <NUM> surrounds at least a portion of a fluid collection assembly, comprising one or more fluid collection layers that evacuate, draw through or absorb the voided urine. The fluid collection assembly is positioned within the external covering <NUM>, with a portion of the fluid collection assembly exposed at the fenestration <NUM>. In the embodiment shown, the fluid collection assembly includes an outer collection layer <NUM> and an inner collection core <NUM>. In some embodiments, one or both of these layers are moisture wicking layers that evacuate the discharged fluid away from the body (e.g. by wicking or capillary effect). In this way, the layer(s) in direct contact with the anatomy do not feel wet to the user or cause dampness on the user's skin, improving user comfort. Furthermore, drawing urine away from the urethral opening of the user assists with preventing urine from leaking or flowing into the surrounding environment (e.g., a bed or chair). In other embodiments, one or more of the fluid collection layers absorb and hold fluid, in combination with or instead of wicking the fluid away.

In some embodiments, the outer collection layer <NUM> is formed of a material having a high absorptive and/or adsorption rate, and a high permeation rate such that urine can be rapidly wicked and diverted to the cavity of the device <NUM>. <FIG> depict examples of outer collection layers <NUM> that are fluid permeable (e.g., urine permeable) and have moisture-wicking properties. In one example, the outer collection layer <NUM> is manufactured of a piece of jersey mesh material, such as that used to make athletic clothing, as shown in <FIG>. The outer collection layer <NUM> may be made of polyester or a blend of polyester and spandex (e.g., a peephole mesh comprising <NUM>% polyester and <NUM>% spandex and weighing within <NUM>% of <NUM>). As a further example, shown in <FIG>, the outer collection layer <NUM> has a corrugated surface such that a surface of the outer collection layer <NUM> has open-cell foam ridges and grooves. This corrugated surface is configured to slow fluid flow at the surface and to provide an increased surface area for promoting fluid absorption and/or adsorption. As a further example, shown in <FIG>, the outer collection layer <NUM> has a moisture wicking foam surface manufactured from, for example, a polyurethane foam having open cells (e.g., a polyurethane foam having a density of <NUM>/m<NUM> ( <NUM> lb/ft<NUM>) and a pressure to compress <NUM>% of <NUM> bar (<NUM> psi)). In some configurations, the corrugated layer or foam layer further provides a cushion for surrounding the tube <NUM> in the device <NUM>, to limit discomfort to the user caused by the rigidity of the tube <NUM>.

Referring to <FIG>, in some embodiments, the outer collection layer <NUM> has one or more indicators 40a configured to assist a person (e.g., a healthcare worker) with optimal positioning of the device in relationship to the urethral opening of a patient. In some embodiments, the outer collection layer <NUM> has one or more raised ridges or grooves running therethrough, such as ridge 40b shown in <FIG>, creating raised grooves and ridges configured to slow the flow of fluid at the surface of the outer collection layer <NUM>, which increases its ability to wick fluid and allow more efficient fluid flow through the outer collection layer <NUM> to the inner collection core <NUM>. Grooves could also be sized and configured to wick urine away using capillary action.

Referring back to <FIG>, an inner collection core <NUM> is positioned within the external covering <NUM> and inside of the outer collection layer <NUM>. In some embodiments, the inner collection core <NUM> is positioned relative to the outer collection layer <NUM> so as to support and maintain the position of the outer collection layer <NUM> across the fenestration <NUM>. The inner collection core <NUM> is formed of any suitable material and has suitable shape that allows for collecting fluid and/or directing fluid flow into an inner cavity of the device <NUM>. The inner collection core <NUM>, in this embodiment, is further configured to reduce the contact pressure of the tube <NUM> on the body of a user. For example, in some embodiments, the inner collection core <NUM> is a flexible material. In some embodiments, the inner collection core <NUM> is manufactured of a polyester filter material (e.g., Nu-Foam formed of a polyester staple fiber of polyethylene terephthalate) that draws the fluid from the outer collection layer <NUM> and wicks it into the cavity without retaining the fluid.

According to an exemplary embodiment, the tube <NUM> is manufactured of a semirigid material and extends within the external covering <NUM> between the open first end <NUM> and the open second end <NUM>. Tube <NUM> allows a vacuum (e.g. a pressure lower than ambient air pressure) to be produced in the cavity of external covering <NUM> when suction is applied to the tube <NUM>, such that fluid collected within the device <NUM> is evacuated from device <NUM> through tube <NUM>. Tube <NUM> has a first end <NUM> configured to extend out from the first open end of the external covering <NUM> and a second end <NUM> terminating within the cap <NUM> (described below). Tube <NUM> is configured to evacuate fluid out from cap <NUM>.

<FIG> depicts an exemplary positioning and use of the urine collection device <NUM> for a female patient. As shown in <FIG>, the collection device <NUM> forms to the curvature of the female anatomy, and the lower end of the collection device <NUM> is configured to be secured or tucked between the gluteal folds and the perineum. In this way, the collection device <NUM> is in a position such that when the patient voids, the fluid is absorbed by or drawn through one or more fluid collection layers of the collection device <NUM> (described below), collected into a body of the collection device <NUM> and then diverted to a reservoir away from the body.

The urine collection device <NUM>, according to an exemplary embodiment, includes a shape retaining element. The shape retaining element is a bendable element that is configured to conform the fluid collection assembly to a curved configuration for placement against the body of the user and maintain the curved configuration of the fluid collection assembly until the configuration is adjusted. In some embodiments, as depicted in <FIG>, the tube <NUM> provides the shape retaining element and is configured to affect and/or hold the shape of device <NUM>. In one example, shown in <FIG>, tube <NUM> is pre-bent into a shape having a curvature 32a conforming to the anatomical contours of a typical user (e.g., conforming to a majority of female patients) and maintains the shape during use. In some embodiments, tube <NUM> is manufactured of a polyurethane material, such as McMaster Polyurethane Tubing for Water, that maintains a pre-bent shape.

In another example, tube <NUM> has an adjustable shape (i.e., the curvature of tube <NUM> is adjustable). In such an embodiment, tube <NUM> is flexible such that it can be manipulated by a person (e.g., a healthcare provider or a user) in various directions and is configured to retain its shape following the manipulation. The curvature of device <NUM> is adjustable, for example, to fit the anatomical curvature of any user. In one embodiment, shown in <FIG>, adjustable tube <NUM> is surrounded by links movable relative to one another, such that a configuration of the tube is able to be maintained once the tube <NUM> is bent into a particular shape. In one such embodiment, adjustable tube <NUM> includes linking segments <NUM> arranged sequentially along a longitudinal direction of adjustable tube <NUM>. Each of the linking segments <NUM> has a first portion 36a, a second portion 36b, and a third portion 36c. Each portion is hollow or has at least an open portion for passing the tube <NUM> therethrough. The first portion 36a includes a spherically shaped body with an opening therein. The first portion 36a is connected to a second hollow portion 36b having a cylindrical shape and a passage therethrough for passing the tubing. The second portion 36b is connected to third hollow portion 36c having a semi-spherical shape and forming a hollow cup. The first hollow portion 36a (the spherical shape) of one segment is configured to fit within the hollow cup of the third hollow portion 36c of an immediately successive segment. In this way, the linked segments include a series of individual segments linked to (e.g., by snapping together) a successive individual segment, wherein each segment is able to move relative to the successive segment as the spherical first portion 36a moves within the hollow cup of the third portion 36c. In yet another example, the adjustable tube <NUM> is formed by the segments <NUM>, rather than the tube <NUM> being surrounding the segments <NUM>. Each one of the segments <NUM> defines a passage therethrough, whereby the first end of any one segment is coupled to the second end of an adjoining segment in such a manner as to form a substantially continuous passage for a fluid. In yet another embodiment, the tube <NUM> is coupled to the outside of an adjustable set of linked segments <NUM> that are hollow or solid.

In yet another example, shown in <FIG>, tube <NUM> has an adjustable shape (i.e., the curvature of tube <NUM> is adjustable). In such an embodiment, tube <NUM> is flexible such that it can be manipulated by a person (e.g., a healthcare provider or a user) in various directions and is configured to retain its shape following the manipulation. The curvature of device <NUM> is adjustable to fit the anatomy of any user. In one such embodiment, adjustable tube <NUM> includes a one or more wires 32c attached to (e.g., embedded within) a wall of adjustable tube <NUM>. As one example, the one or more wires 32c are embedded within an inner wall of adjustable tube <NUM>. The one or more wires 32c are configured to provide a flexibility to adjustable tube <NUM>, which allows for manipulation by a person to adjust the shape of adjustable tube <NUM>, and retains the shape once formed. A further example includes one or more bellows associated with the tube <NUM> that are capable of being shaped and conformed to the user by pressure differentials caused by the application of air flow into or out of the device through the tube <NUM>. Air flow could inflate or deflate bellows or segments that would conform the device <NUM> to the anatomy of the user.

In a still further example, shown in <FIG>, tube <NUM> has an adjustable shape (i.e., the curvature of tube <NUM> is adjustable). In such an embodiment, tube <NUM> is flexible such that it can be manipulated by a person (e.g., a healthcare provider or a user) in various directions and is configured to retain its shape following the manipulation. The curvature of device <NUM> is adjustable, for example, to fit the anatomy of any user. In one such embodiment, adjustable tube <NUM> includes bellows 32d arranged sequentially along a longitudinal direction of tube <NUM>. The bellows 32d are configured to allow a person to manipulate the shape of the adjustable tube <NUM> and retain the shape once formed. In some embodiments, the tube itself forms the bellows, and in other embodiments, the tube is surrounded by and/or coupled to an accessory providing the bellows.

Alternatively, in some embodiments, the tube <NUM> is provided separately from the adjustable, shape retaining element that allows the device <NUM> to be manipulated into and keep a shape (e.g., be shaped into and maintain a curved configuration for placement against the body of a patient until the configuration is adjusted). For example, a shape retaining element is provided in the center of the device <NUM>, and the tube <NUM> is provided next to the shape retaining element, outside of the device <NUM>, and so on. Any of the foregoing examples that allow for adjustability of the device can be provided separate from the tube <NUM>.

<FIG> illustrates a shape retaining element <NUM>, according to an exemplary embodiment. In the embodiment shown in <FIG>, the shape retaining element <NUM> includes a number of linking segments <NUM>. As shown in <FIG>, the linking segments <NUM> are similar to the linking segments <NUM> described above with reference to <FIG>, including a first portion 36a with a spherically shaped body, a second portion 36b with a cylindrical shape, and a third portion 36c having a semi-spherical shape forming a hollow cup. As such, the linking segments <NUM> are configured to fit together by the first portion 36a of a first linking segment <NUM> fitting into a third portion 36c of a second linking segment <NUM> such that the linking segments <NUM> are movable relative to each other. Additionally, as further shown in <FIG>, the linking segments <NUM> are hollow such that, when the linking segments <NUM> are connected together to form the shape retaining element <NUM>, a solid core <NUM> is provided along the center of the shape retaining element <NUM>. As such, the linking segments <NUM> of the shape retaining element <NUM> are not in fluid communication with each other.

<FIG> illustrates another shape retaining element <NUM>, according to an exemplary embodiment. In the embodiment of <FIG>, the shape retaining element <NUM> again includes a number of linking segments <NUM>. However, as shown in <FIG>, the linking segments <NUM> according to this embodiment include a cap portion 36d on top of the first portion 36a. As such, when the linking segments <NUM> are connected together to form the shape retaining element <NUM>, the linking segments <NUM> are each closed off from each other such that, for example, the linking segments <NUM> of the shape retaining element are not in fluid communication with each other.

<FIG> illustrates a lengthwise cross-section of another shape retaining element <NUM>, according to an exemplary embodiment. The shape retaining element <NUM> according to <FIG> is again formed from a number of linking segments <NUM> connected together. These linking segments <NUM> are primarily similar to the linking segment <NUM> shown in <FIG>, with each linking segment <NUM> having a hollow first portion 36a, second portion 36b, and third portion 36c without any cap portions. However, the first and last linking segments of the shape retaining element <NUM> are cap linking segments <NUM> and are configured similarly to the linking segment <NUM> shown in <FIG>, with each cap linking segment <NUM> also having a cap portion 36d. As such, because the cap linking segments <NUM> include cap portions 36d, the shape retaining element <NUM>, as a whole, is not in fluid communication with surrounding fluids of the device <NUM>.

<FIG> illustrates a lengthwise cross-section of another shape retaining element <NUM>, according to an exemplary embodiment. The shape retaining element <NUM> according to <FIG> is similar to the shape retaining element <NUM> shown in <FIG>, being formed from a number of hollow linking segments <NUM> and capped by two cap linking segments <NUM>. However, the center of the shape retaining element <NUM> is also provided with a solid core <NUM> extending through the hollow centers of the linking segments <NUM>. Alternatively, in some embodiments, the core <NUM> is replaced with a tube (e.g., similar to the tube <NUM>) that is thus fully contained within the shape retaining element <NUM>. The shape retaining element <NUM> is provided with the core <NUM> or with a tube, for example, to ensure that the shape retaining element <NUM> is subject to "global bends," or bends extending smoothly along the extent of the shape retaining element <NUM>, rather than "local bends," or bends extending only along localized areas of the shape retaining element <NUM>.

<FIG> illustrates another linking segment <NUM> used to form a shape retaining element, according to an exemplary embodiment. As shown in <FIG>, the linking segment <NUM> includes a first portion 36a with a hollow spherically shaped body, a second portion 36b with a hollow cylindrical shape, and a third portion 36c having a semi-spherical shape forming a hollow cup. Additionally, third portion 36c is formed with a number of slots 36e spaced around the linking segment <NUM>. As such, when linking segments <NUM> according to <FIG> are connected together, as shown in <FIG>, the linking segments <NUM> do not allow fluid flow (e.g., urine or air flow created by suction) between each other due to the slots 36e. In this way, the linking segments <NUM> are connected together to form a shape retaining element <NUM>, as shown in <FIG>, that does not provide for fluid communication along the lengthwise extent of the shape retaining element <NUM>.

<FIG> illustrates another linking segment <NUM> used to form a shape retaining element, according to an exemplary embodiment. As shown in <FIG>, the linking segment <NUM> includes a first portion 36a with a hollow spherically shaped body, a second portion 36b with a hollow cylindrical shape, and a third portion 36c having a semi-spherical shape forming a hollow cup. Additionally, the second portion 36b is provided with one or more holes 36f. As such, when the linking segments <NUM> according to <FIG> are connected together to form a shape retaining element <NUM>, as shown in <FIG>, the linking segments <NUM> do not allow fluid flow (e.g., urine or air flow created by suction) between each other due to the holes 36f.

<FIG> illustrate another linking segment <NUM> used to form a shape retaining element, according to an exemplary embodiment. As shown in <FIG>, the linking segment <NUM> includes a first portion 36a with a hollow spherically shaped body, a second portion 36b with a hollow cylindrical shape, and a third portion 36c having a semi-spherical shape forming a hollow cup. However, the third portion 36c is provided with two slots 36e forming a member <NUM> between them. As such, one side of the linking segment forms a flange while the other side is largely open. Due to this, the linking segments <NUM> according to <FIG> are connected together to form a shape retaining element <NUM> that allows for a one-way bend because the flanged side of the linking elements <NUM> blocks a backwards bend. Moreover, the members <NUM> facilitate a global bend along the shape retaining element <NUM> by allowing for a uniform radius of curvature. In some embodiments, the ends of the shape retaining element <NUM> are closed off (e.g., by being provided with linking segments including cap portions 36d). Additionally, as shown in <FIG>, the linking segments <NUM> are provided with a larger number of slots 36e creating a larger number of members <NUM> such that the shape retaining element <NUM> is bendable in more than one direction.

It should be understood that the shape retaining elements <NUM> illustrated in <FIG> are exemplary and that other shape retaining elements <NUM> may instead be used with a urine collection device. For example, a flexible tube or solid element may be impregnated with or be wrapped in a coiled foil or mesh made up of a thin flexible metal to form a shape retaining element <NUM>, with the coiled foil or mesh configured to be flexible and hold the shape of the element <NUM> when bent. As another example, the coiled foil or mesh is used by itself as a shape retaining element <NUM>. The flexible mesh or element may be molded into the flexible tube or flexible solid element such as by co-extrusion.

In some embodiments, the device <NUM> is otherwise configured to conform to the curvature of the user and to maintain its shape while in use. In one example, the device <NUM> or the tube <NUM> may be constructed with a bias to a curved configuration. The bias is provided, for example, by a spring, or by one or more memory shaped wires or supports associated with the device <NUM> or the tube <NUM>. In this way, the device <NUM> is naturally inclined to a curved position, optionally, a tight curvature. For positioning on the user, the device <NUM> can be "opened" or otherwise straightened, and then released when placed in a proper location, thereby held tightly against the user's body in a conformed configuration by the biasing force.

In another example, a device is individually configured to a user to provide a custom fit. This is achieved, for example, through curation of a polymer after setting the device to a proper fit for the user. As an example, a molded plastic part is warmed such that the proper shape can be set as it cools in a proper position on the user. In another example, an external light source assists with curing the device to have a custom fit.

In yet another example, the application of suction can also be used to shape and conform the device to the user by creating vacuum. For example, once the suction is turned on, the reduced pressure created within the device body can draw in or otherwise act upon the body to move it to a curved configuration that corresponds with the user's anatomy. In some embodiments, the device includes one or more bellows capable of being shaped and conformed to the user by pressure differentials caused by air flow into or out of the bellows. Air flow could inflate or deflate bellows or segments that would conform the device <NUM> to the anatomy of the user. Similarly, in other embodiments, the reduced pressure created in the cavity of the device holds and maintains the unit in place, in addition to being useful for conforming to the wearer's body. In this way, the use of suction may draw in or otherwise engage the device <NUM> with the user's body.

As shown in <FIG>, according to an exemplary embodiment, the second end <NUM> of the tube <NUM> has a slit, aperture, or cut out portion, such as aperture 34a, to better allow air flow into the cap <NUM> while the suction is applied. The space created between the second end <NUM> of the tube <NUM> and the cap <NUM> by the slit, aperture, or cut prevents the second end <NUM> from being suctioned to and forming an air tight seal against the cap <NUM>, which would prevent the flow of the collected urine through the tube <NUM>.

In some embodiments, the tube <NUM> extends all the way from the device <NUM> to a fluid collection reservoir <NUM>, as depicted in <FIG> and described in further detail below. However, in other embodiments, tube <NUM> terminates at the first end <NUM> of the tube, and is coupled at the first end <NUM> to a curved tube extension <NUM>, as shown in <FIG>. In such embodiments, the curved tube extension <NUM> is an intermediate element between the tube <NUM> and a discharge tube line <NUM> that is coupled between the device <NUM> and the collection reservoir <NUM> as shown in <FIG>. The curved tube extension <NUM> is used to modify the direction at which the tube <NUM> and discharge tube line <NUM> extend. It is advantageous that the tubing be directed away from the user's body, such as off the side of the bed, rather than extending up towards the head of the user. This prevents the tubing from accidental pulling, risking leakage by pulling the device out of its placement in relation to the urethral opening of a user, or being an irritation to the user. Accordingly, the curved tube extension <NUM> directs the tubing immediately off to the side of the user, without causing a bend and possible kink in the tube which may occur when attempting to bend a straight tube. In some embodiments, the first end <NUM> of the tube <NUM> is formed to have a curvature making the bend, thereby eliminating the need for a separate curved tube extension <NUM> element.

In some embodiments, the curved tube extension <NUM> is capable of rotation relative to the first end <NUM> of the tube <NUM> so a user or another person disposing the device on the body of a user is able to direct the tubing to extend in any direction, for example, in a preferred direction depending on where the collection reservoir is placed relative to the user.

Referring again to <FIG>, the urine collection device <NUM> further includes cap <NUM> at the open second end <NUM> of the external covering <NUM>. Cap <NUM> is coupled to the second open end of the external covering <NUM>, and a water-tight seal is formed therebetween. Cap <NUM> acts as a reservoir for diverted fluid which has been collected by the device <NUM> from the urethral opening of a user. As described above, the second end <NUM> of the tube is disposed in the cap <NUM>, such that fluid is drawn through the tube <NUM> from within the cap <NUM>. In some embodiments, cap <NUM> has an outer surface configured to secure the device in position relative to the user, i.e. between the gluteal folds within the perineum. In some embodiments, the cap <NUM> is sized and configured to hold together the ends of the tube <NUM>, the inner collection core <NUM>, and the outer collection layer <NUM> such that the urine collected and drawn through the inner collection core <NUM> and outer collection layer <NUM> is diverted (i.e., due to gravity or a reduced pressure created in the cap by suction through the tube <NUM>) and collected in the cap <NUM>. The cap <NUM> is configured to collect and hold urine that has been expelled from the urethral opening of a user for a temporary period of time until the urine is removed from the device through the tube <NUM>. In some embodiments, the cap <NUM> is any suitable shape and/or size capable of collecting fluid removed from the urethral opening of a user and passed through the outer collection layer <NUM> of the device <NUM>.

Cap <NUM> is attached to device <NUM> by any suitable means. In one example, cap <NUM> is attached (e.g., secured, connected, etc.) to the open second end <NUM> of device <NUM> by tape. In a further example, as shown in <FIG>, cap <NUM> is attached or connected to the open second end <NUM> by shrink wrapping <NUM> wound around cap <NUM> and the open second end <NUM>, thus securing cap <NUM> to the open second end <NUM> of device <NUM>.

In some embodiments, cap <NUM> has a cup-like shape. In some embodiments, cap <NUM> is manufactured of a material that is biocompatible (e.g., will not induce an immune response in a user), soft so as not cause pressure points, and/or flexible. Cup-shaped cap <NUM> is, for example, formed of silicone rubber or other polymeric material which may be certified as USP Class-IV.

In some embodiments, cap <NUM> has a wedge shape, as shown in the various embodiments illustrated in <FIG>. A wedged-shaped cap has a cup portion with a tapered surface configured to fit into the gluteal folds and perineum of the body of a user such that cap <NUM> stays in position on the body of a user.

In some embodiments, an external portion of the cap <NUM> has an adhesive portion. The adhesive portion is configured to secure device <NUM> to the body of a user between the gluteal folds such that device <NUM> stays in position on the body of a user. In some embodiments, the adhesive portion is made of any suitable biocompatible material (e.g., does not induce an immune response in a user). For example, the adhesive portion is made of a silicone based adhesive with certifications for cytotoxicity, skin irritation, and skin sensitization. The adhesive portion may be an adhesive coating or material applied to the exterior of the cap <NUM>, or may be a piece of adhesive material adhered to the exterior of the cap <NUM>.

Referring again to <FIG>, the urine collection device <NUM> includes an anchor <NUM> connected to the device <NUM> at or adjacent to the open first end <NUM> of the external covering <NUM>. The anchor <NUM> is configured to secure the device <NUM> in position to collect and transport urine voided by a user. The shape of the anchor <NUM> is configured to conform to the surface area of the skin of the pelvic region of the user without pulling or pinching the skin or bunching up in ways that would cause discomfort. Anchor <NUM> has any suitable shape and structure to secure the device to the body of a user and to remain secured despite a wearer's motion, moisture accumulation on the body, or passage of time. In the embodiment shown in <FIG>, anchor <NUM> includes a center portion configured to attach to the body of a user between the pubic region and the umbilical region, with two wing portions extending outward towards the lateral regions of the body. In another embodiment, as shown in <FIG>, anchor <NUM> has a shape extending in a more lateral manner relative to the device, having a narrower central portion 51a and wider wing portions 51b on each side of the central portion 51a. In this embodiment, the anchor <NUM> is particularly suited for the specific patient, depending on age, weight, body composition, or other factors that may dictate the size of the anchor <NUM>. For example, the laterally extending anchor <NUM> in <FIG> may provided in a first size (up to approximately <NUM> centimeters in length), a second size (between approximately <NUM> centimeters and <NUM> centimeters in length), a third size (between approximately <NUM> centimeters and <NUM> centimeters in length), and/or a fourth size (between approximately <NUM> centimeters and <NUM> centimeters in length). Similarly, the laterally extending anchor <NUM> in <FIG> may be provided having different widths, for example a first size (up to approximately <NUM> centimeters wide), a second size (between approximately <NUM> centimeters and <NUM> centimeters wide), a third size (between approximately <NUM> centimeters and <NUM> centimeters wide, and/or a fourth size (between approximately <NUM> centimeters and <NUM> centimeters wide). A health care professional may have a variety of anchors from which to choose from in the above ranges, and may select the anchor most appropriate for the user.

Alternatively, the anchor <NUM> includes wider portions that are not connected by a central portion. As an illustration, <FIG> depicts an embodiment of a urine collection device <NUM> designed such that a body of the device <NUM> bifurcates into two ends <NUM> (e.g., into a "Y" shape), and each end is provided with a wider portion 51b. Accordingly, the two wider portions 51b move independently from each other. Such a design may allow for a more customized fit to a patient, as the bifurcations and separate portions <NUM>1b allow the device <NUM> to be more flexibly fitted to a patient in placing the device <NUM> due to more degrees of freedom.

In some embodiments, anchor <NUM> includes an external film for covering an adhesive layer, which is configured to be easily removable using a tab or tabs that are part of the external film or are connected to the external film. In some embodiments, anchor <NUM> further includes a tab configured to allow a person (e.g., a healthcare provider) to remove the anchor <NUM> from the body of a user without causing discomfort or harm to the body of a user when attempting to remove. The anchor <NUM> and adhesive layer may be of such a configuration to avoid portions of the body that are covered with hair, since adhering the anchor to these portions of the body could result in uncomfortable pulling or removing hair upon removal of the anchor <NUM>. According to some embodiments, only a portion of the anchor <NUM> includes adhesive for securing to the user. For example, only the outer edges of the anchor <NUM> include an adhesive area, or only the inner areas not extending to the outer edges include the adhesive area. In yet another example, only certain portions or plots within the anchor <NUM> area include adhesive. Various configurations and placement of adhesive may be used to best accommodate securing the anchor <NUM> and the device <NUM> to the user's body without over-use of adhesive.

According to some embodiments, the anchor <NUM> is constructed having separate and removable portions, such that the anchor <NUM> has a variable shape and/or dimension. For example, the anchor <NUM> has perforations such that certain distal portions or entire areas of the anchor <NUM> can be removed to better fit the body of the user. The anchor <NUM> is, alternatively, adjustable to allow for varying the dimension of the anchor.

The anchor <NUM> may be any suitable biocompatible material which may be used with the skin of a user, such as human skin. In some embodiments, anchor <NUM> is stretchable. In some embodiments, anchor <NUM> is manufactured of a urethane or other polymeric material film adhesive having a foam backing configured to provide strength, stability, and support. For example, the adhesive layer is silicone based with a minimal amount of acrylic or none at all. In some embodiments, the adhesive is a Dow Coming Soft Skin Adhesive MG <NUM>-<NUM>. In some embodiments, the foam backing provides a layer to prevent the tube <NUM> from rubbing against the skin adjacent to the pelvic region of the user.

Anchor <NUM> is attached to device <NUM> by any suitable means. In one example, anchor <NUM> is attached (e.g., secured, connected, etc.) to the open first end <NUM> of device <NUM> by tape that secures anchor <NUM> to open first end <NUM>. In a further example, as shown in <FIG>, anchor <NUM> is attached or connected to the open first end <NUM> by shrink wrapping <NUM> wound around an end of anchor <NUM> and the open first end <NUM>, thus securing anchor <NUM> to the open first end <NUM> of device <NUM>.

In other embodiments, the anchor portion is provided for use in association with the device <NUM>, but that is not directly coupled to the device <NUM>. For example, an adhesive portion is provided to secure the tube <NUM> or discharge tube line <NUM> to the user, but not necessarily to secure the device <NUM> itself to the user. In another embodiment, an anchor <NUM> as described above may be provided with the device <NUM>, but that is not directly coupled to the device <NUM> during production. In yet another embodiment, the device does not include anchor <NUM> at all, and is able to be fixed relative to the body by another fixation mechanism exemplified below.

For example, in addition to or instead of anchor <NUM>, the device <NUM> includes another fixation mechanism such as an elastic band or strap. In this example, the band or strap is coupled to the device <NUM> and configured to wrap around the user's waist or leg, for example. Similarly, the device <NUM> may be configured to be used in association with a wearable garment, such as a brief that is used to hold the device <NUM> in position relative to the user's body. In yet another example, a projection extends from the device <NUM> that is configured to be inserted into the vagina of the user to maintain the positioning of the device <NUM>.

As mentioned previously, in some embodiments, the cap <NUM> also provides for fixation of the device relative to the body. Referring again to <FIG>, the various shapes of the cap <NUM> provide for associating the device with the body in a more secure relationship. For example, the wedge-shaped cap <NUM> shown in the embodiment of <FIG> fits with the anatomy, such as in the gluteal folds, the gluteal cleft, or the perineum. In this way, the device <NUM> is more securely fixed relative to the body. In some embodiments, the cap <NUM> also has adhesive on the outer surface to increase the fixation even further. In some embodiments, the device <NUM> includes an additional adhesive area, either along the sides or the distal end of device <NUM> to assist with fixation. The additional adhesive area may be a second anchor configured for attachment to the user's body. The additional adhesive area may also be located along the sides of the device <NUM>. The additional adhesive area may be used instead of anchor <NUM> and/or cap <NUM> adhesive, or may be used in combination with one or both.

Finally, as mentioned previously, the application of the suction may be used to hold the device <NUM> securely in place on the user's body. For example, the suction may be used to form the device <NUM> in a curvature corresponding to the user's anatomy in such a tight way that the engagement of the device <NUM> with the body is secure. In another example, the pressure differential between the inside of the device <NUM> and the ambient air surrounding the user causes the device <NUM> to be drawn in towards, and in direct contact with the skin of the user, which may be maintained securely until the suction creating the vacuum condition is inactivated.

In some embodiments, the device <NUM> also includes a wedge formed at or near open first end <NUM> of device <NUM> in an area intended to be positioned near the urethral opening of the patient. The wedge is configured to separate the labia majora and labia minora of the body of a user to maintain and direct fluid flow directly to the device <NUM> surface from the urethral opening. In some embodiments, shown for example in <FIG>, the wedge includes an orifice with a cylindrical shaped protuberance configured to fit over the urethra of the body of a user such that fluid flow is diverted from urethral opening through an internal cavity of device <NUM> and into cap <NUM>. In some embodiments, shown for example in <FIG>, the wedge is manufactured of a fabric and configured to be disposed over the urethral opening of the body of a user and collect fluid voided from the urethral opening of the user. In yet another embodiment, shown for example in <FIG>, a urethral funnel <NUM> is disposed over the urethra of a user. The urethral funnel includes a backsplash that redirects voided fluid to a tube configured to evacuate fluid at a recess within the tube.

According to some embodiments, such as the embodiment of <FIG>, <FIG>, and <FIG>, external covering <NUM> does not form a cylindrical body as shown in the embodiments of <FIG>, and is alternatively a fluid impermeable backing formed by a sheet of fluid impermeable material wrapped around an underside of the fluid collection assembly (i.e., around a portion of the inner collection core <NUM> and outer collection layer <NUM>). The fluid impermeable material may be enclosed around the fluid collection assembly on each end by tape or by shrink wrap material as described above. In this embodiment, a portion of the external covering <NUM> is attached (e.g., secured, connected, etc.) to outer collection layer <NUM> by any suitable means. For example, as shown in <FIG>, <FIG>, and <FIG>, edges of the external covering <NUM> are secured to the outer collection layer <NUM>. In one specific example, edges of external covering <NUM> are sewn to the outer collection layer <NUM> along line <NUM>. In another specific example, edges of external covering <NUM> are ultrasonically welded to the outer collection layer <NUM> along line <NUM>. Accordingly, in such embodiments, the fenestration for receiving urine includes the top portion of the device <NUM> not covered by the external covering <NUM> (e.g., the top half of the device <NUM> shown in <FIG>).

<FIG> illustrates another embodiment of the urine collection device <NUM> with a fluid impermeable backing. Additionally, the device <NUM> shown in <FIG> is flatter and wider than the device <NUM> shown in <FIG>. As illustrated in an exploded view of the device <NUM> shown in <FIG>, the device <NUM> includes similar components in the fluid collection assembly of the device <NUM> as those shown in <FIG>. Accordingly, the device <NUM> shown in <FIG> includes a collection layer <NUM> (e.g., created from a permeable fabric) provided on the top side of the device <NUM>, an external covering <NUM> configured as a fluid impermeable backing, and a cap <NUM> (e.g., with a smooth bottom for a close fit to the patient's anatomy). The inner collection core <NUM> is provided as a first layer 42a of batting that surrounds a second layer 42b of batting, which in turn surrounds the tube <NUM>. The device <NUM> also includes a suction tubing adaptor <NUM> that allows the tube <NUM> in the device <NUM> to be fitted to a separate length of external tubing, such as suction tubing, or another device, such as a suction device.

Further, the fluid impermeable backing includes a shape retaining element <NUM> provided in the form of a core integrated into the backing. In various embodiments, the core is a metal core (e.g. aluminum, lead, copper, stainless steel, or any type of soft metal) or a plastic core. For example, in one embodiment, the core of the shape retaining element <NUM> includes one or more shape memory wires configured to provide a bias to the device <NUM>. As shown, the device <NUM> includes one shape retaining element <NUM>, though in other embodiments the device <NUM> includes more than one shape retaining element <NUM> (e.g., two or more). The shape retaining element <NUM> is incorporated into the external covering <NUM>, for example, by wrapping or encasing the shape retaining element. In some arrangements, the shape retaining element <NUM> is integrated into the external covering <NUM> by encasing the shape retaining element <NUM> in foam of the external covering <NUM>. In other arrangements, the shape retaining element <NUM> is insulated or heat shrink dipped and incorporated into the external covering <NUM>. It should be understood, however, that the device <NUM> may be formed into a different shape and/or include a different shape retaining element <NUM>. For example, the device <NUM> may be formed into a Y-shape, similar to the device <NUM> shown in <FIG>, with a similar Y-shaped shape retaining element <NUM> formed into the external covering <NUM>.

<FIG> illustrate another embodiment of the urine collection device <NUM> with a fluid impermeable backing. As shown in <FIG>, the device <NUM> includes a shape retaining element <NUM> formed from hollow linking elements <NUM> provided with core <NUM> (e.g., in the form of a tube, as illustrated in <FIG>, or as a solid core). As illustrated in <FIG>, the shape retaining element <NUM> is inserted into a center of the device <NUM> to allow the device <NUM> to be shaped and maintain its shape, as described above with reference to <FIG>. The core <NUM> is configured to support the device <NUM> rather than facilitate the removal of fluid from the device <NUM>. It should further be understood that the device <NUM> may be provided with any of the shape retaining elements <NUM> described above with reference to <FIG>.

Moreover, the device <NUM> shown in <FIG> includes an external tube <NUM> that fits into and extends out of the cap <NUM> to divert fluid away from the device <NUM>. The external tube <NUM> replaces the internal tube that fits into the body of the device <NUM> as shown, for example, in <FIG>. As illustrated in <FIG>, fluid flows into the device <NUM> via the outer collection layer <NUM>, is collected in the cap <NUM>, and is subsequently diverted from the device <NUM> via the external tube <NUM> connected to the cap <NUM>. The external tube <NUM> has numerous degrees of freedom, allowing the tube <NUM> to be positioned away from the patient as needed. In some embodiments, a hook <NUM> is provided on a top surface of the device <NUM> into which the external tube <NUM> is tucked or slid (e.g., to ensure that the external tube <NUM> is not accidentally pulled out of the cap <NUM> and the device <NUM>). Alternatively, in some embodiments, the tube <NUM> is provided in the impermeable layer of the external covering <NUM> (e.g., in addition to, or instead of, a shape retaining element <NUM> provided in the impermeable layer of the external covering <NUM> similar to the element <NUM> shown in <FIG>).

Further, the second end <NUM> of the external tube <NUM> is provided with a tubing adaptor <NUM> such that the tube <NUM> is connectable to a second length of tube (e.g., suction tubing) leading away from the patient or to another device (e.g., a suction device). <FIG> illustrate exemplary embodiments of the adaptor <NUM>. <FIG> illustrates a male adaptor <NUM>, and <FIG> illustrates a female adaptor <NUM>. The male adaptor <NUM> includes step tapering, for example, to help ensure that the adaptor <NUM> fits snugly within the second tube or device. By contrast, the female adaptor <NUM> includes an opening into which the second length of tube may be inserted and may also include step tapering within the opening. However, the adaptors <NUM> shown in <FIG> are meant to be exemplary. As such, in other embodiments, the adaptor <NUM> is replaced with a different connector, such as a first side of a snap that fits into a corresponding second side of a snap on a suction tube/device, or a detent piece that fits inside of a suction tube/device. Additionally, in some embodiments, the adaptor includes or is connected to, or the external tube <NUM> is otherwise provided with, a diverter valve that allows a user to change the flow of fluid to a different attachment and/or a stop valve that allows a user to turn off the flow of fluid from the device <NUM>. The diverter valve would allow for the flow of urine to a separate collection receptacle such as that meant for testing samples of the collected urine.

As discussed above, the first end <NUM> of the external tube <NUM> is inserted into the cap <NUM> to couple the tube <NUM> to the device <NUM>. <FIG> illustrate the cap <NUM>, according to an exemplary embodiment. As shown in <FIG>, the cap <NUM> has a smooth, elongated, wedge shape with curved sides configured to fit patient anatomy. The cap <NUM> includes an open end <NUM> configured to fit onto the open second end <NUM> of the device <NUM>. The open end <NUM> includes a flange <NUM>, and the inside surface of the cap <NUM> is provided with ribbing <NUM> to help ensure a snug fit between the cap <NUM> and the second end <NUM> of the device <NUM>. The cap <NUM> also includes a port <NUM> into which the first end <NUM> of the external tube <NUM> is inserted to couple the tube <NUM> to the cap <NUM>, for example, by threading the first end <NUM> into the port <NUM>. As shown in <FIG>, the port <NUM> extends near the open end <NUM> at an angle from the side of the cap <NUM>. However, it should be understood that in other embodiments, the port <NUM> is provided anywhere on the cap <NUM> or, in some embodiments, elsewhere on the device <NUM>. Alternatively, the cap <NUM> does not include a port <NUM> and may instead include a tubing adaptor <NUM> that connects directly to external suction tubing or an external suction device. In some embodiments, the cap <NUM> includes elements in addition to those depicted in <FIG>, such as a relief valve or a holding element similar to the holding element described below with reference to <FIG>.

In some embodiments, the first end <NUM> of the device <NUM> is also provided with a cap, such as the top cap <NUM> illustrated in <FIG>. As shown, the top cap <NUM> includes a connecting end <NUM> that extends out to form a tab <NUM>, which is configured to secure the device <NUM> to the patient (e.g., by conforming to the patient's anatomy). The connecting end <NUM> includes a rim <NUM> configured to fit around the first end <NUM> of the device <NUM>, as well as a holding feature <NUM> configured to hold an inside solid or tubular flexible element, such as a shape retaining element, through an annular fit. The connecting end <NUM> is also provided with a hook <NUM>, which may be similar to the hook <NUM> and hold an external tube <NUM> in place during use of the device <NUM>. The connecting end <NUM> also includes holes <NUM> that extend through the width of the connecting end <NUM> and serve as vent holes or valves to prevent skin suction (e.g., when the device <NUM> is connected to a suction element in order to vacate the device <NUM> of fluid).

<FIG> illustrates another embodiment of a urine collection device <NUM> with the external covering <NUM> designed as a fluid impermeable backing. In the embodiment of <FIG>, the external covering <NUM> is formed from a number of backing tubes 20d provided side-by-side to form a fluid impermeable surface. The backing tubes 20d are, for example, extruded together, adhered together, stitched together, or otherwise connected together to form the fluid impermeable surface of the external covering <NUM>. Additionally, at least one of the backing tubes 20d is provided with the a tube <NUM> fitted within the backing tube 20d to allow for the direction of fluid into the cap <NUM> (not shown in <FIG>) and out of the device <NUM>.

The device <NUM> may be made of various materials and components as described above. Any of the materials used for the components of device <NUM> described above may be an antimicrobial material or fabric, or have an antimicrobial treatment applied thereto.

Referring now to <FIG>, a system <NUM> for collecting urine that is discharged from the body of a user and carrying the collected urine away from the body is shown. The system includes the urine collection device <NUM> for collecting urine that is discharged from the body of a user. The system further includes discharge tube line <NUM> coupled to the tube <NUM> of the collection device <NUM> and disposed between the tube <NUM> and external collection reservoir <NUM>. The system further includes an air pump or vacuum source <NUM> for providing suction through the tube <NUM>, connected to the external receptacle via a vacuum line <NUM>. In some embodiments, the discharge tube line <NUM> and the vacuum line <NUM> both comprise a flexible tubing (e.g., flexible plastic tubing). In some embodiments, the external reservoir <NUM> is a sealed container. In some embodiments, the external reservoir <NUM> is disposable. In some embodiments, the external collection reservoir <NUM> is configured to be sterilized after a use and reused. In some embodiments, tube <NUM> of the collection device <NUM> and the discharge tube line <NUM> are manufactured as a single piece of tubing.

The vacuum source <NUM> has a sufficiently high vacuum strength such that rapid air and liquid aspiration is maintained over at least a portion of the permeable membrane. In some embodiments, the vacuum source <NUM> can be a pump that is commercially available and configured to run continuously or sporadically. In some embodiments, the vacuum source <NUM> is a wall vacuum already integrated into the room of a medical facility. For example, the vacuum line <NUM> is directly connected to a vacuum regulator in the room.

<FIG> is a flowchart illustrating an exemplary method <NUM> for using a device for collecting and evacuating urine that is discharged from the body of a patient. The device used in method <NUM> is the same or similar in structure and/or function to any of the devices disclosed and described with reference to <FIG>.

In step <NUM>, the vacuum line <NUM> is coupled to the vacuum source <NUM>. In step <NUM>, the discharge tube line <NUM> is coupled to the fluid collection reservoir <NUM>. In step <NUM>, the urine collection device, such as urine collection device <NUM> is coupled to the patient. <FIG> is a flowchart depicting the substeps involved in step <NUM> for positioning the device on the patient.

In step <NUM>, the free end of the discharge tube line <NUM> is coupled to the device <NUM>, via the first end <NUM> of the tube <NUM>. At this time, it should be confirmed that all tubing is free of obstacles. In some embodiments, the discharge tube line <NUM> is coupled to a curved tube extension <NUM>. In step <NUM>, suction is activated by way of the vacuum source such that urine voided from the patient can be collected and removed from the patient. In some embodiments, there could be continuous suction. In some uses, the suction remains activated for an extended period of time such that it is always effective for collecting and removing voided urine. In other uses, the suction is selectively activated only when needed, such as when the patient has voided.

In step <NUM>, the device is removed from the body of a patient. Following step <NUM>, the method may be repeated using a second, clean device for collecting and removing urine from the body of a patient. The device may need to be replaced periodically, such as every <NUM> or <NUM> hours, and should be disposed of according to hospital protocol. The anchor <NUM>, if it is a separate piece, may be replaced after a longer period of time, such as <NUM>, <NUM>, <NUM>, or <NUM> hours or longer. In some situations, the device may need to be replaced more or less often depending on several factors, including maintenance of proper positioning, leakage, volume of urine collected, and any other factors which may require sooner replacement or may allow the device to be used for a greater length of time.

At any time during the above method, a user or a caregiver may re-assess and correct the fit and positioning of the device, such as immediately after placement, after initial activation of the suction, after an extended period time, after patient repositioning, etc..

<FIG> is a flowchart depicted the sub-steps of positioning the device in contact with the patient in step <NUM>. Prior to positioning the device, the caregiver may perform the proper hand hygiene and perineal care per hospital protocol. In step <NUM>, the patient's legs are separated. In step <NUM>, the patient's labia is separated using one hand. In step <NUM>, using the other hand, the device is held vertically with cap <NUM> facing-downward and the fenestration <NUM> facing the patient's labia. Prior to this step, the caregiver may need to remove the device <NUM> from device packaging. In step <NUM>, the edge of the device is aligned with the perineum and outer collection layer <NUM> is positioned against the urethral opening. In step <NUM>, the cap <NUM> is secured between the patient's gluteal folds. In some embodiments where there is adhesive on the cap <NUM>, the adhesive is secured between the patient's gluteal folds. In step <NUM>, the labia is released.

In step <NUM>, the anchor <NUM> is bent toward the pubic region. In this step, the caregiver may need to hold the device in this curvature until the anchor <NUM> is secured, or in the embodiment with the adjustable tube, the device will maintain this curvature after it is adjusted. In some cases, the device <NUM> already has the proper curvature such that no bending or adjustment is necessary. In step <NUM>, the liner covering the adhesive is removed and the anchor <NUM> is smoothed over the patient's suprapubic region. Once the device is positioned and the proper placement is confirmed, the patient's legs should be closed to further secure the device in place.

Accordingly, when properly placed, the device should be positioned such that the at least one fenestration <NUM> of the device is in operative relation with a urethral opening of the patient such that urine discharged from the urethral opening is received by the device (e.g., the fluid collection assembly of the device, as described above) at the at least one fenestration <NUM>. For example, the device should be positioned in a vertical orientation such that the at least one fenestration <NUM> is in operative relation with a urethral opening of a female patient. The urine is then directed into the cap <NUM>, as described above, and evacuated from the device via the tube (e.g., via an internal tube <NUM> running inside the length of the device from the cap <NUM> to the open second end <NUM> or by an external tube <NUM> coupled to the cap <NUM>). It should further be understood that a process similar to step <NUM> may be used to position the device with respect to a male patient but instead of separating and placing the device with respect to the patient's labia, the device is positioned, for example, in a cup-shaped configuration with at least one fenestration in operative relation with a urethral opening of a male user.

As utilized herein, the terms "approximately," "about," "substantially," and similar terms are intended to have a broad meaning in harmony with the common and accepted usage by those of ordinary skill in the art to which the subject matter of the present disclosure pertains. It should be understood by those of skill in the art who review the present disclosure that these terms are intended to allow a description of certain features described and claimed without restricting the scope of these features to the precise numerical ranges provided. Accordingly, these terms should be interpreted as indicating that insubstantial or inconsequential modifications or alterations of the subject matter described and claimed are considered to be within the scope of the present disclosure as recited in the appended claims.

The terms "coupled," "connected," and the like as used herein mean the joining of two members directly or indirectly to one another. Such joining may be stationary (e.g., permanent) or moveable (e.g., removable or releasable). Such joining may be achieved with the two members or the two members and any additional intermediate members being integrally formed as a single unitary body with one another or with the two members or the two members and any additional intermediate members being attached to one another.

References herein to the position of elements (e.g., "top," "bottom," "above," "below," etc.) are merely used to describe the orientation of various elements in the FIGURES.

Claim 1:
A device (<NUM>) for collecting urine discharged from a body of a user, comprising:
a fluid collection assembly comprising at least one layer (<NUM>, 42a, 42b) for drawing urine discharged from the body of the user into an interior cavity of the device (<NUM>);
an external covering (<NUM>) that covers a portion of the fluid collection assembly;
at least one fenestration (<NUM>) for receiving urine, wherein the at least one fenestration (<NUM>) is a portion of the fluid collection assembly that is uncovered by the external covering (<NUM>);
a cap (<NUM>) enclosing a first end of the fluid collection assembly;
a tube (<NUM>) having a first end in fluid communication with the cap;
a shape retaining element (<NUM>) configured to conform the fluid collection assembly to a curved configuration for placement against the body of the user and maintain the curved configuration of the fluid collection assembly until the configuration is adjusted; and
wherein the fluid collection assembly is configured to be disposed against the body of the user, with the at least one fenestration (<NUM>) in operative relation with a urethral opening of the user such that urine discharged from the urethral opening is received by the fluid collection assembly at the at least one fenestration (<NUM>), directed into the cap, and then evacuated through the tube (<NUM>)
characterised by
an anchor (<NUM>) configured to secure the fluid collection assembly in position relative to a user.