Patent Description:
Briefly summarized, embodiments disclosed herein are directed to systems, methods and apparatuses for determining the tension of a catheter tubing extending from a patient to a drainage bag and automatically adjusting the positioning of the drainage bag when the tension is outside of a preferred range.

Some examples of automated drainage bag actuation systems are disclosed in e.g. <CIT> and <CIT>.

One problem that often arises with catheter tubing, especially when coupled to a bed frame, is the existence a dependent loop due to a lack of tension within the catheter tubing. One cause of dependent loops in catheter tubing is the length of tubing utilized. Excess tubing may be utilized by medical professionals to enable a patient to move (e.g., roll side to side, sit up, etc.). Although necessary to provide comfort for and the ability to move to the patient, excess tubing may lead to dependent loops.

A dependent loop in the catheter tubing includes a section of the tubing that is positively sloping, which requires fluid to overcome gravity before the fluid reaches the drainage bag. Multiple problems arise with a dependent loop including that the fluid in the tube is not measured and the fluid often gets caught within the dependent loop. Therefore, a medical professional may not obtain an accurate reading of the fluid passed by the patient and as a result, incorrectly assess the status of the patient's health.

A second problem resulting from a dependent loop is that the fluid passed by the patient is required to overcome gravity in order to reach the drainage bag, thus requiring a higher pressure exerted by the bladder to flow. The exertion of higher pressure may cause damage to the patient and even cause fluid to be held within the bladder thereby increasing the risk of infection. Embodiments of the disclosure provide for systems, methods and apparatuses that measure the amount of tension in the catheter tubing and automatically adjust the positioning of the drainage bag when necessary such that the tension in the catheter tubing once again falls within a preferred range. As a result, the patient maintains comfort and fluid is able to flow to the drainage bag using gravity due to a continuous negative slope along the length of the tubing.

An automated drainage bag actuation system is disclosed that comprises a first railing, a control box coupled to the first railing and configured to receive mounting fasteners that couple a drainage bag to the control box, the control box including a tension load cell sensor, a first motor and circuitry electrically coupled to the first motor and the tension load cell sensor. In some embodiments, the circuitry is configured to receive data from the tension load cell sensor indicating an amount of tension in tubing extending from the drainage bag and transmit one or more electrical signals to activate the first motor causing adjustment of a positioning of the drainage bag.

In some embodiments, the automated drainage bag actuation system further comprises an infrared (IR) sensor coupled to the circuitry, the IR sensor configured to obtain a distance measurement of a distance between the IR sensor and a ground surface or intervening object, wherein the one or more electrical signals activating the first motor are based in part on the distance measurement.

In some embodiments, the automated drainage bag actuation system further comprises a second railing coupled to the first railing. In one embodiment, activation of the first motor causes adjustment of the positioning of the drainage bag in a vertical direction along the second railing. In an alternative embodiment, activation of the first motor causes adjustment of the positioning of the drainage bag rotationally about the second railing.

In some embodiments, the automated drainage bag actuation system further comprises a base including a second motor, wherein the circuitry is configured to receive the data from the tension load cell sensor indicating the amount of tension in the tubing extending from the drainage bag and transmit the one or more electrical signals to activate the second motor causing adjustment of the positioning of the drainage bag.

In yet other embodiments, the automated drainage bag actuation system further comprises one or more tracks, wherein activation of the second motor causes horizontal movement along the one or more tracks. In further embodiments, the second motor causes rotation of the drainage bag about a vertical axis.

In some embodiments, the first railing is a horizontal railing and activation of the first motor causes horizontal movement of the drainage bag along the first railing. The circuitry may be located within the control box.

Additionally, a method of automatically adjusting a positioning of a drainage bag is disclosed. The method comprises operations of providing an automated drainage bag actuation system that includes a first railing, a control box coupled to the first railing and configured to receive mounting fasteners that couple a drainage bag to the control box, the control box including a tension load cell sensor, a first motor, and circuitry electrically coupled to the first motor and the tension load cell sensor.

In some embodiments of the method, the automated drainage bag actuation system further comprises an infrared (IR) sensor coupled to the circuitry, the IR sensor configured to obtain a distance measurement of a distance between the IR sensor and a ground surface or intervening object, wherein the one or more electrical signals activating the first motor are based in part on the distance measurement.

In some embodiments of the method, the automated drainage bag actuation system further comprises a second railing coupled to the first railing. In one embodiment of the method, activation of the first motor causes adjustment of the positioning of the drainage bag in a vertical direction along the second railing. In an alternative embodiment of the method, activation of the first motor causes adjustment of the positioning of the drainage bag rotationally about the second railing.

In some embodiments of the method, the automated drainage bag actuation system further comprises a base including a second motor, wherein the circuitry is configured to receive the data from the tension load cell sensor indicating the amount of tension in the tubing extending from the drainage bag and transmit the one or more electrical signals to activate the second motor causing adjustment of the positioning of the drainage bag.

In yet other embodiments of the method, the automated drainage bag actuation system further comprises one or more tracks, wherein activation of the second motor causes horizontal movement along the one or more tracks. In further embodiments of the method, the second motor causes rotation of the drainage bag about a vertical axis.

In some embodiments of the method, the first railing is a horizontal railing and activation of the first motor causes horizontal movement of the drainage bag along the first railing. The circuitry may be located within the control box.

These and other features of the concepts provided herein will become more apparent to those of skill in the art in view of the accompanying drawings and following description, which disclose particular embodiments of such concepts in greater detail, the invention being defined by the appended claims.

Embodiments of the disclosure are illustrated by way of example and not by way of limitation in the figures of the accompanying drawings, in which like references indicate similar elements and in which:.

Regarding terms used herein, it should be understood the terms are for the purpose of describing some particular embodiments, and the terms do not limit the scope of the concepts provided herein.

With respect to "proximal," a "proximal portion" or a "proximal end portion" of, for example, a probe disclosed herein includes a portion of the probe intended to be near a clinician when the probe is used on a patient. Likewise, a "proximal length" of, for example, the probe includes a length of the probe intended to be near the clinician when the probe is used on the patient. A "proximal end" of, for example, the probe includes an end of the probe intended to be near the clinician when the probe is used on the patient. The proximal portion, the proximal end portion, or the proximal length of the probe can include the proximal end of the probe; however, the proximal portion, the proximal end portion, or the proximal length of the probe need not include the proximal end of the probe. That is, unless context suggests otherwise, the proximal portion, the proximal end portion, or the proximal length of the probe is not a terminal portion or terminal length of the probe.

With respect to "distal," a "distal portion" or a "distal end portion" of, for example, a probe disclosed herein includes a portion of the probe intended to be near or in a patient when the probe is used on the patient. Likewise, a "distal length" of, for example, the probe includes a length of the probe intended to be near or in the patient when the probe is used on the patient. A "distal end" of, for example, the probe includes an end of the probe intended to be near or in the patient when the probe is used on the patient. The distal portion, the distal end portion, or the distal length of the probe can include the distal end of the probe; however, the distal portion, the distal end portion, or the distal length of the probe need not include the distal end of the probe. That is, unless context suggests otherwise, the distal portion, the distal end portion, or the distal length of the probe is not a terminal portion or terminal length of the probe.

The term "logic" may be representative of hardware, firmware or software that is configured to perform one or more functions. As hardware, the term logic may refer to or include circuitry having data processing and/or storage functionality. Examples of such circuitry may include, but are not limited or restricted to a hardware processor (e.g., microprocessor, one or more processor cores, a digital signal processor, a programmable gate array, a microcontroller, an application specific integrated circuit "ASIC", etc.), a semiconductor memory, or combinatorial elements.

Additionally, or in the alternative, the term logic may refer to or include software such as one or more processes, one or more instances, Application Programming Interface(s) (API), subroutine(s), function(s), applet(s), servlet(s), routine(s), source code, object code, shared library/dynamic link library (dll), or even one or more instructions. This software may be stored in any type of a suitable non-transitory storage medium, or transitory storage medium (e.g., electrical, optical, acoustical or other form of propagated signals such as carrier waves, infrared signals, or digital signals). Examples of a non-transitory storage medium may include, but are not limited or restricted to a programmable circuit; non-persistent storage such as volatile memory (e.g., any type of random access memory "RAM"); or persistent storage such as non-volatile memory (e.g., read-only memory "ROM", power-backed RAM, flash memory, phase-change memory, etc.), a solid-state drive, hard disk drive, an optical disc drive, or a portable memory device. As firmware, the logic may be stored in persistent storage.

Referring to <FIG>, a perspective view of an exemplary hospital room environment including a hospital bed on which a patient is located is shown according to some embodiments. <FIG> illustrates an exemplary drainage bag <NUM> coupled to a hospital bed <NUM> on which a patient <NUM> is located via mounting fasteners <NUM>. Catheter tubing <NUM> is illustrated as extending from the patient <NUM> (e.g., which may include an inflatable balloon configured to be disposed within the patient <NUM>'s bladder) to the drainage bag <NUM> at a distal end of the tubing <NUM>.

In particular, <FIG> illustrates a problem that often arises with catheter tubing, especially when coupled to a bed frame. The tubing <NUM> is positioned such that a dependent loop is formed in the length of the tubing <NUM>. One cause of dependent loops in catheter tubing is the length of tubing utilized. As the patient <NUM> is not always immobile while lying in the hospital bed <NUM>, excess tubing is utilized by medical professionals to enable the patient <NUM> to move (e.g., roll side to side, sit up, etc.). Although necessary to provide comfort for and the ability to move to the patient <NUM>, excess tubing may lead to dependent loops.

As illustrated, the dependent loop in the tubing <NUM> includes a section of the tubing that is positively sloping, which requires fluid to overcome gravity before the fluid reaches the drainage bag <NUM>. Multiple problems arise with a dependent loop. For example, one problem includes the fact that the fluid in the tube is not measured and fluid often gets caught within the dependent loop. Therefore, a medical professional may not obtain an accurate reading of the fluid passed by the patient <NUM> and as a result, incorrectly assess the status of the health of the patient <NUM>. A second problem resulting from a dependent loop is that the fluid passed by the patient <NUM> is required to overcome gravity in order to reach the drainage bag <NUM>, thus requiring a higher pressure exerted by the bladder to flow. The exertion of higher pressure may cause damage to the patient <NUM> and even cause fluid to be held within the bladder thereby increasing the risk of infection.

Referring to <FIG>, a side view of a hospital bed coupled to a first embodiment of a drainage bag actuation system being in a first position is shown according to some embodiments. <FIG> illustrates a hospital room environment <NUM> in which a patient <NUM> is located on a hospital bed <NUM>. In the illustration, the hospital bed <NUM> includes at least a mattress <NUM> and a bed frame railing <NUM>.

In contrast to the illustration of <FIG> in which the drainage bag <NUM> is coupled to the bed frame railing, the embodiment of <FIG> illustrates a drainage bag actuation system <NUM> coupled to the bed frame railing <NUM> and the drainage bag <NUM> coupled to the drainage bag actuation system <NUM>. The drainage bag <NUM> is shown to be coupled to the control box <NUM> with the mounting fasteners <NUM>. It should be noted that the drainage bag <NUM> and the mounting fasteners <NUM> may be utilized both in the current technology (e.g., coupled directly to the bed frame railing as shown in <FIG>) and with multiple embodiments of the disclosure. Specifically, one benefit the embodiments of the disclosure provide is that the drainage bag actuation systems <NUM>, <NUM> and <NUM> (of <FIG>, <FIG> and <FIG> respectively) do not require a new drainage bag or mounting mechanism from that currently being utilized in hospitals and other medical facilities.

The drainage bag actuation system <NUM> includes system railing <NUM>, a control box <NUM>, expandable rail components 216A-216B, a vertical displacement motor <NUM>, a horizontal displacement motor <NUM>, movement logic and/circuitry ("movement logic") <NUM>, a tension load cell sensor <NUM> and an infrared (IR) sensor <NUM>. The vertical displacement motor <NUM>, the horizontal motor <NUM> and any other motor described herein may include a rotary actuator, a linear actuator, a closed-loop servomechanism or, more specifically, a servomotor. In some embodiments, a stepper motor may be utilized.

The IR sensor <NUM> may include an IR light emitter and an IR light detector. The IR sensor <NUM> emits an IR light beam, detects the reflection off of a surface and calculates the distance through triangulation. In the illustration of <FIG>, the drainage bag actuation system <NUM> is illustrated in a first position, wherein the first position refers to a raised position with the expandable rail components 216A-216B in a compressed state. In comparison, <FIG> illustrates the drainage bag actuation system <NUM> in a second position, wherein the second position refers to a lowered position with the expandable rail components 216A-216B in an expanded state.

The embodiment of the drainage bag actuation system <NUM> illustrated in <FIG> may automatically adjust the positioning of the drainage bag <NUM> by moving the control box <NUM> in order to alter the positioning of the catheter tubing <NUM> to remove any dependent loops. Therefore, the drainage bag actuation system <NUM> provides numerous benefits to medical professionals and medical patients by solving problems of the embodiment illustrated in <FIG> as discussed above. Specifically, by automatically adjusting the positioning of the drainage bag <NUM> to remove dependent loops within the catheter tubing <NUM>, the drainage bag actuation system <NUM> creates a negative slope in the tubing <NUM>. As a result, fluid does not get caught in the tubing <NUM> and the bladder of the patient <NUM> does not have to exert pressure for the fluid to reach the drainage bag <NUM>.

The drainage bag actuation system <NUM> includes movement logic <NUM> within the control box <NUM> that obtains measurements from the tension load cell sensor <NUM> and determines whether tension of the catheter tubing <NUM> is within a predetermined preferred range. Upon determining that the tension of the tubing <NUM> exceeds an upper threshold of the predetermined preferred range, the movement logic <NUM> provides an electrical signal to either the vertical displacement motor <NUM> and/or the horizontal displacement motor <NUM> thereby activating one or both motors.

Activating the vertical displacement motor <NUM> causes the expandable rail components 216A-216B to expand moving the drainage bag actuation system <NUM> from a first (raised) position to a second (lowered) position. Activation of the vertical displacement motor <NUM> may be dependent on measurements obtained by the IR sensor <NUM>, which indicate a distance between a ground surface (or intervening object, collectively referred to as "ground surface" for purposes of clarity) and a location of the IR sensor <NUM>. For example, a measurement taken by the IR sensor <NUM> is provided to the movement logic <NUM> prior to activating the vertical displacement motor <NUM>. Based on known dimensions of the drainage bag <NUM> (which may be modified via configuration files of the movement logic <NUM>), the movement logic <NUM> determines the distance between the bottom of the drainage bag <NUM> and the ground surface based on the distance calculation by the IR sensor <NUM>.

When the distance is greater than a minimum distance threshold, the movement logic <NUM> may activate the vertical displacement motor <NUM> to move the system railings <NUM> in a downward direction (i.e., toward the ground surface). The movement logic <NUM> may receive measurements from the IR sensor <NUM> and the tension load cell sensor <NUM> at regular intervals while the vertical displacement motor <NUM> is activated. The measurements (received via electrical signals) enable the movement logic <NUM> to determine (i) when the tension of the catheter tubing <NUM> is within the predetermined preferred range, and (ii) when the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to the minimum distance threshold. In the situation in which the tension of the catheter tubing <NUM> is above an upper threshold of the predetermined preferred range and the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to the minimum distance threshold, the movement logic <NUM> may deactivate the vertical displacement motor <NUM> and activate the horizontal displacement motor <NUM>. However, it should be noted that the horizontal displacement motor <NUM> may be activated prior to the vertical displacement motor <NUM>. The determination as to an ordering of motor activation may be made on contents of a configuration file that is accessible to the movement logic <NUM> (e.g., stored with, included as part of or otherwise accessible by the movement logic <NUM>). Similarly, other movement logic of the disclosure may access a configuration file when determining an ordering of activation of motors.

When the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to (or exceeds) the minimum distance threshold, the movement logic <NUM> does not activate the vertical displacement motor <NUM> in order to avoid placing the drainage bag <NUM> close to or in direct contact with the ground surface. Instead, the movement logic <NUM> may activate the horizontal displacement motor <NUM> causing the control box <NUM> to move horizontally.

During activation of any motor of the drainage bag actuation system <NUM>, the movement logic <NUM> receives measurements from the tension load cell sensor <NUM> at regular intervals in order to deactivate the motor(s) when the tension of the tubing <NUM> is within the predetermined preferred range.

Referring now to <FIG>, a side view of the hospital bed of <FIG> coupled to the drainage bag actuation system being in a second position is shown according to some embodiments. As illustrated in <FIG>, the expandable rail components 216A-216B have been moved from a first (raised) position to a second (lowered) position and the control box <NUM> has moved from a first position to a second position horizontally distal to the head of the patient <NUM>. As a result of the movements of the drainage bag actuation system <NUM>, the tension in the tubing <NUM> has increased such that the dependent loop has been removed.

Referring to <FIG>, a perspective view of a hospital bed coupled to a second embodiment of a drainage bag actuation system is shown according to some embodiments. <FIG> illustrates a hospital room environment <NUM> in which a patient <NUM> is located on a hospital bed <NUM> that includes a bed frame railing <NUM>. In a similar manner as illustrated in <FIG>, catheter tubing <NUM> extends from the patient <NUM> to the drainage bag <NUM>, which is not coupled directly to the bed frame railing <NUM>. In <FIG>, the drainage bag <NUM> is coupled to a drainage bag actuation system <NUM> using the mounting fasteners <NUM> as seen in <FIG>.

The drainage bag actuation system <NUM> includes a vertical rail <NUM>, a horizontal rail <NUM>, a tension control box <NUM>, a movement control box <NUM>, a slidable platform <NUM>, floor tracks <NUM>, a first motor <NUM>, a second motor <NUM> and movement logic and/circuitry ("movement logic") <NUM>. Additionally, the drainage bag actuation system <NUM> includes components included in the drainage bag actuation system <NUM> and discussed above such as the tension load cell sensor <NUM> and the IR sensor <NUM>.

In the illustration of <FIG>, the drainage bag actuation system <NUM> is illustrated in a first position, wherein the first position refers to a first vertical position of the movement control box <NUM>, a first rotational position of the movement control box <NUM> and a first horizontal position of the slidable platform <NUM>. Although a second or other position is not illustrated, the drainage bag actuation system <NUM> may be placed in a second position as a result of movement caused by either the first motor <NUM> within the movement control box <NUM> or by the second motor <NUM> within the slidable platform <NUM>.

In particular, the embodiment of the drainage bag actuation system <NUM> illustrated in <FIG> may automatically adjust the positioning of the drainage bag <NUM> by moving either the movement control box <NUM> and/or the slidable platform <NUM>. The movement control box <NUM> may be moved in either vertically or rotationally about the vertical rail <NUM>. The slidable platform <NUM> may be moved horizontally along the floor tracks <NUM>. As with the drainage bag actuation system <NUM> of <FIG>, one function of the drainage bag actuation system <NUM> is to alter the positioning of the catheter tubing <NUM> to remove any dependent loops. As such, the drainage bag actuation system <NUM> provides the same benefits as discussed above with respect to <FIG>.

The drainage bag actuation system <NUM> includes movement logic <NUM> within the slidable platform <NUM> that obtains measurements from the tension load cell sensor <NUM> and determines whether tension of the catheter tubing <NUM> is within a predetermined preferred range in a similar manner as discussed above with respect to the drainage bag actuation system <NUM>. Upon determining that the tension of the tubing <NUM> exceeds an upper threshold of the predetermined preferred range, the movement logic <NUM> provides an electrical signal to either the first motor <NUM> and/or the second motor <NUM> thereby activating one or both motors.

Activation of the first motor <NUM> may be in a vertical direction and/or rotationally about the vertical railing <NUM>. The drainage bag actuation system <NUM> includes the IR sensor <NUM> (e.g., at an end of the horizontal railing <NUM>) which determines the distance between the IR sensor <NUM> and a ground surface. As with the movement logic <NUM>, the movement logic <NUM> utilizes known dimensions of the drainage bag <NUM> to determine a distance between the bottom of the drainage bag <NUM> and the ground surface. The vertical movement of the movement control box <NUM> is dependent on the distance between the bottom of the drainage bag <NUM> and the ground surface.

When the distance between the bottom of the drainage bag <NUM> and the ground surface is greater than a minimum distance threshold, the movement logic <NUM> may activate the first motor <NUM> to move the movement control box <NUM> in a downward direction. The movement logic <NUM> may receive measurements from the IR sensor <NUM> and the tension load cell sensor <NUM> at regular intervals while the first motor <NUM> is activated. The measurements (received via electrical signals) enable the movement logic <NUM> to determine (i) when the tension of the catheter tubing <NUM> is within a predetermined preferred range, and (ii) when the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to the minimum distance threshold. In the situation in which the tension of the catheter tubing <NUM> is above an upper threshold of the predetermined preferred range and the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to the minimum distance threshold, the movement logic <NUM> may instruct the first motor <NUM> to stop the downward movement of the movement control box <NUM> and either activate (i) the first motor <NUM> to rotate the movement control box <NUM>, and/or (ii) the second motor <NUM> causing the slidable platform <NUM> to move horizontally along the floor tracks <NUM>.

When the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to (or exceeds) the minimum distance threshold, the movement logic <NUM> does not activate the first motor <NUM> in order to avoid placing the drainage bag <NUM> close to or in direct contact with the ground surface. Instead, as discussed above, may either activate (i) the first motor <NUM> to rotate the movement control box <NUM>, and/or (ii) the second motor <NUM> causing the slidable platform <NUM> to move horizontally along the floor tracks <NUM>.

Referring to <FIG>, a perspective view of a hospital bed coupled to a third embodiment of a drainage bag actuation system is shown according to some embodiments. In a similar manner as illustrated in <FIG>, catheter tubing <NUM> extends from the patient <NUM> to the drainage bag <NUM>, which is not coupled directly to the bed frame railing <NUM>. In <FIG>, the drainage bag <NUM> is coupled to a drainage bag actuation system <NUM> using the mounting fasteners <NUM> as seen in <FIG>.

The drainage bag actuation system <NUM> includes a vertical rail <NUM>, a horizontal rail <NUM>, a tension control box <NUM>, a movement control box <NUM>, a base <NUM>, a first motor <NUM>, an optional second motor <NUM> and movement logic and/circuitry ("movement logic") <NUM>. Additionally, the drainage bag actuation system <NUM> includes components included in the drainage bag actuation systems <NUM>, <NUM> and discussed above such as the tension load cell sensor <NUM> and the IR sensor <NUM>.

In the illustration of <FIG>, the drainage bag actuation system <NUM> is illustrated in a first position, wherein the first position refers to a first vertical position and a first rotational position of the movement control box <NUM>. Although a second or other position is not illustrated, the drainage bag actuation system <NUM> may be placed in a second position as a result of movement caused by either the first motor <NUM> within the movement control box <NUM> or by the optional second motor <NUM> within the base <NUM>.

In particular, the embodiment of the drainage bag actuation system <NUM> illustrated in <FIG> may automatically adjust the positioning of the drainage bag <NUM> by moving the movement control box <NUM> either in a vertical direction or rotationally about the railing <NUM>. As with the drainage bag actuation systems <NUM>, <NUM>, one function of the drainage bag actuation system <NUM> is to alter the positioning of the catheter tubing <NUM> to remove any dependent loops. As such, the drainage bag actuation system <NUM> provides the same benefits as discussed above with respect to <FIG>.

The drainage bag actuation system <NUM> includes movement logic <NUM> within the base <NUM> that obtains measurements from the tension load cell sensor <NUM> and determines whether tension of the catheter tubing <NUM> is within a predetermined preferred range in a similar manner as discussed above with respect to the drainage bag actuation systems <NUM>, <NUM>. Upon determining that the tension of the tubing <NUM> exceeds an upper threshold of the predetermined preferred range, the movement logic <NUM> provides an electrical signal to either the first motor <NUM> and/or the optional second motor <NUM> thereby activating one or both motors.

Activation of the first motor <NUM> may be in a vertical direction and/or rotationally about the vertical railing <NUM>. The drainage bag actuation system <NUM> includes the IR sensor <NUM> (e.g., at an end of the horizontal railing <NUM>) which determines the distance between the IR sensor <NUM> and a ground surface. As with the movement logic <NUM>, <NUM>, the movement logic <NUM> utilizes known dimensions of the drainage bag <NUM> to determine a distance between the bottom of the drainage bag <NUM> and the ground surface. The vertical movement of the movement control box <NUM> is dependent on the distance between the bottom of the drainage bag <NUM> and the ground surface.

When the distance between the bottom of the drainage bag <NUM> and the ground surface is greater than a minimum distance threshold, the movement logic <NUM> may activate the first motor <NUM> to move the movement control box <NUM> in a downward direction. The movement logic <NUM> may receive measurements from the IR sensor <NUM> and the tension load cell sensor <NUM> at regular intervals while the first motor <NUM> is activated. The measurements (received via electrical signals) enable the movement logic <NUM> to determine (i) when the tension of the catheter tubing <NUM> is within a predetermined preferred range, and (ii) when the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to the minimum distance threshold. In the situation in which the tension of the catheter tubing <NUM> is above an upper threshold of the predetermined preferred range and the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to the minimum distance threshold, the movement logic <NUM> may instruct the first motor <NUM> to stop the downward movement of the movement control box <NUM> and activate the first motor <NUM> to rotate the movement control box <NUM>.

When the distance between the bottom of the drainage bag <NUM> and the ground surface is equal to (or exceeds) the minimum distance threshold, the movement logic <NUM> does not activate the first motor <NUM> in order to avoid placing the drainage bag <NUM> close to or in direct contact with the ground surface. Instead, as discussed above, may activate the first motor <NUM> to rotate the movement control box <NUM>.

In some embodiments, such as any of those disclosed herein, the drainage bag systems <NUM>, <NUM>, <NUM> may include alarm logic that is configured to activate an alarm when a continuous negative slope cannot be created within the tubing <NUM>. For example, when the tension of the tubing <NUM> is not within the predetermined preferred range and additional movement of the components of the drainage bag system is not possible (e.g., the bottom of the drainage bag <NUM> is too close to the ground surface and no rotation mechanism has not been implemented in the embodiment), an alarm may be activated that alerts medical professionals to assess the patient and the status of the catheter.

In any of the embodiments discussed above, the movement logic may perform a tension release operations that automatically adjust the positioning of the drainage bag to provide slack (e.g., to reduce the tension in the tubing) when the tension load cell sensor obtains a measurement indicating that the tension in the tubing is above a maximum threshold of the predetermined (e.g., preferred) range. For instance, the patient may have previously rolled toward the drainage bag reducing the amount of tension in the tubing causing a dependent loop. As a result, the drainage bag actuation system may have automatically adjusted the positioning of the drainage bag to increase the amount of tension in the tubing in order to remove the dependent loop. However, as the patient subsequently rolls away from the drainage bag increasing the tension in the tubing, the amount of tension in the may exceed a maximum threshold of the predetermined preferred range. At which time, the drainage bag actuation system may automatically adjust the positioning of the drainage bag to reduce the tension in the tubing.

Referring to <FIG>, a flowchart illustrating an exemplary method for automatically adjusting a positioning of a drainage bag is shown according to some embodiments. Each block illustrated in <FIG> represents an operation performed in the method <NUM> performed by a drainage bag actuation system, such as any of the drainage bag actuation systems <NUM>, <NUM>, <NUM> discussed above. The method <NUM> starts when a measurement indicating an amount of tension in a catheter tubing is obtained (block <NUM>). In some embodiments, as discussed above, the amount of tension in the tubing is obtained using a tension load cell sensor of the drainage bag actuation system.

Subsequent to the tension load cell sensor obtaining the amount of tension in the tubing, the drainage bag actuation system determines whether the measurement of the amount of tension is greater than or equal to a predetermined tension threshold (block <NUM>). When the measurement is not greater than or equal to the tension threshold, no action is taken (block <NUM>).

Claim 1:
An automated drainage bag actuation system (<NUM>, <NUM>, <NUM>), comprising:
a first railing (<NUM>, <NUM>);
a control box (<NUM>, <NUM>, <NUM>) coupled to the first railing (<NUM>, <NUM>) and configured to receive mounting fasteners (<NUM>) that are configured to couple a drainage bag (<NUM>) to the control box (<NUM>, <NUM>, <NUM>), the control box (<NUM>, <NUM>, <NUM>) including a tension load cell sensor (<NUM>);
a first motor (<NUM>, <NUM>, <NUM>); and
circuitry (<NUM>, <NUM>, <NUM>) electrically coupled to the first motor (<NUM>, <NUM>, <NUM>) and the tension load cell sensor (<NUM>),
wherein the circuitry (<NUM>, <NUM>, <NUM>) is configured to receive data from the tension load cell sensor (<NUM>) configured to indicate an amount of tension in tubing (<NUM>) extending from the drainage bag (<NUM>) and transmit one or more electrical signals to activate the first motor (<NUM>, <NUM>, <NUM>) configured to cause adjustment of a positioning of the drainage bag (<NUM>).