Prone positioning therapeutic bed

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to therapeutic beds, and more particularly to an improved rotating bed capable of placing a patient in a prone position.

2. Long-felt Needs and Description of the Related Art

Patient positioning has been used in hospital beds for some time to enhance patient comfort, prevent skin breakdown, improve drainage of bodily fluids, and facilitate breathing. One of the goals of patient positioning has been maximization of ventilation to improve systematic oxygenation. Various studies have demonstrated the beneficial effects of body positioning and mobilization on impaired oxygen transport. The support of patients in a prone position can be advantageous in enhancing extension and ventilation of the dorsal aspect of the lungs.

Proning has been recognized and studied as a method for treating acute respiratory distress syndrome “ARDS”) for more than twenty-five years. Some studies indicate that approximately three quarters of patients with ARDS will respond with improved arterial oxygenation when moved from the supine to the prone position.

There are several physiological bases for patient proning. When a person lies flat in the supine position, the heart and sternum lie on top of and compress the lung volume beneath it. Moreover, the abdominal contents push upward against the diaphragm and further compress and increase the pressures on the most dorsal lung units, where perfusion (i.e., blood flow volume reaching alveolocapillary membranes) is greatest. In an ARDS patient, ventilation in these dorsal regions is inhibited by fluid and cellular debris that settle into the most dependent lung segments. Lung edema may further increase the plural pressures.in the most dependent regions. The combination of fluid accumulation with compression by the heart, sternum, and abdominal contents on the dorsal regions of the lung results in a significant ventilation-perfusion mismatch. Expressed more simply, the air entering the patient's lungs is not reaching those parts of the lungs (the dorsal regions where perfusion is greatest) that most need it.

Flipping a patient into the prone position improves arterial oxygenation through several mechanisms. First, moving the fluid-filled lungs into a nondependent ventral position facilitates drainage of the fluid and cellular debris that had accumulated in and blocked ventilation to the dorsal regions of the lung. Second, the weight of the heart is supported by the sternum, rather than the lungs. When a patient is in the supine position, as much as 25-44% of the lung volume may be displaced by the heart, especially if the heart is enlarged due to cardiovascular disease. Rotating the patient into the prone position can reduce that displacement to as little as 1-4% of lung volume. Third, if the patient is supported in the prone position in a manner that allows the abdomen to protrude, then the abdominal contents no longer push upward onto the diaphragm to compress the lungs.

Proning minimizes the mechanical forces that pressurize distressed alveolar units into collapse, and can also recruit atelectatic but functional units for gas exchange. Proning also causes changes in pleural pressures, which encourages more uniform distribution of ventilation within the lungs. Proning often reduces the intrapulmonary shunt (defined as the portion of blood that enters the left side of the heart without exchanging gases with alveolar gases) and improves arterial oxygenation. The results of proning can be immediate, resulting in significantly improved oxygenation in as little as one hour.

Despite its promises, prone positioning has not been widely practiced on patients because, due to the inadequacies of prior art devices, it is a difficult and labor-intensive process. Logistically, moving a patient to the prone position using prior art technology requires careful planning, coordination, and teamwork to prevent complications such as inadvertent extubation and loss of invasive lines and tubes.

Even when precautions are taken, proning using prior art technology is fraught with potential complications. For example, it is difficult to provide cardiopulmonary resuscitation (“CPR”) to a patient lying in the prone position. Critical time may have to be spent recruiting a team of personnel to move the patient from the prone to the supine position before performing CPR. Accordingly, there is a need for a motor-operated proning device that will quickly rotate a proned patient from the prone position to the supine position. There is also a need for a system that enables a fast, one-step operation to cause the motor-operated proning device to rotate the patient back to a supine position.

A frequently cited complication with prone positioning is the development of pressure ulcers, especially on the forehead, chin, and upper chest wall. Immobility in the prone position can also result in breast and penile breakdown. Some of the most difficult areas to manage in the prone position are the head, face, eyes, and arms. Increased incidence of eye infection due to drainage, corneal abrasions, and even blindness caused by increased intra-ocular pressure have been reported as a consequence of prone positioning. Also, immobility and pressure on the arms have been reported to result in peripheral nerve injury and contractures. Accordingly, there is a need for a proning device that minimizes the risk of pressure-related complications.

Prone positioning using many prior art methods and devices has caused chest tubes, invasive lines, and infusions to become kinked. Worse, the rotation of a patient from the supine to the prone position on some beds has been reported to result in inadvertent extubation and decannulation, which can have catastrophic consequences. Accordingly, there is a need for a proning device with a patient line care management system that will minimize the risk of extubation, decannulation, or kinking of patient care lines.

Proning can also increase the risk of aspiration of gastric acid, food, or other foreign material into the lungs. Aspiration of gastric acid can result in severe pneumonia. Another complication, much more frequent than aspiration, is dependent edema. Most critically ill intensive care unit patients develop dependent edema. When moved into the prone position, the face is put into a dependent position, which often results in significant facial edema. Accordingly, there is a need for a proning device that will minimize aspiration and facial edema.

There are many prior art devices used to facilitate patient proning. One example is the Vollman Prone Device™, made by the Hill-Rom Co., Inc.®. The Vollman Prone Device comprises a set of foam pads to support the patient's head, chest, and pelvis and which are secured to a patient with straps, belts, and buckles while the patient in the supine position. After the foam pads are secured, the patient is manually rotated into the prone position on a regular hospital mattress. Of course, no special device is needed to place a patient in the prone position. Towels, blankets, egg crate mattresses, and foam positioning pads can be used to help maintain proper alignment in the prone position.

One difficulty with devices such as the Vollman Prone Device is that several personnel are still required to turn the patient over. Moreover, medical personnel must revisit the patient frequently to turn the patient toward different positions to prevent pressure sores and other complications from developing.

To make it easier to turn a patient into the prone position, other prior art devices have been provided comprising a rotatable frame to rotate a patient into the prone position. The Stryker Wedge® Turning Frame, for example, comprises a rotatable frame having a supine support surface and a prone support surface in between which a patient is wedged. The frame is manually rotated into the desired position. But the frame still suffers several shortcomings. One of its shortcomings, as with other manually-operated prior art proning devices, is inadequate compliance by medical personnel. Because it is difficult and labor intensive to manually operate a proning bed, many doctors do not begin proning ARDS patients until late in the course of the patient's disease process, after other recruitment measures have failed. However, there is a general consensus that if prone positioning is provided earlier, in the more exudative stages of ARDS, a patient will be more likely to respond positively. Accordingly, there is a need for a therapeutic bed that makes it simpler and less labor-intensive for medical personnel to prone a patient.

Another problem with manually-operated prior art beds such as the Stryker Wedge Frame is that unless manually rocked back and forth, patients will be left immobile, in a fixed position, for extended periods of time. Immobility leads to many of the complications discussed above that hinder the widespread adoption of prone positioning as a therapy for ARDS patients. Accordingly, there is a need for a therapeutic bed that provides not only prone positioning but also automated alternating side-to-side rotational therapy to intermittently relieve pressure from the dependent surfaces of the body.

Other beds made by Kinetic Concepts, Inc.®, such as the TriaDyne® II, also facilitate prone positioning. Specially designed proning cushions have been provided to accommodate moving a patient to the prone position and maintaining the patient there. The TriaDyne's low air loss pressure relief surface reduces the risk of certain complications like skin breakdown. While the TriaDyne has many benefits, its protocol calls for a team of about 5 to 8 people to move a patient from the supine to the prone position. One person should be assigned at the head of the bed to secure and manage the airway during the maneuver. The procedure also calls for the team to disconnect as many of the invasive lines as possible to simply the procedure, and then reconnect them when the patient has been placed in the prone position. Caution must be exercised with head positioning to prevent applying pressure directly to the eyes, ears, or endotracheal tube.

While it is possible to program the TriaDyne to perform continuous lateral rotation therapy while the patient is in the prone position, the TriaDyne is incapable of automatically rotating the patient from the supine to the prone position, and from there applying kinetic therapy. Moreover, the arc of rotation in the prone position is limited because of the absence of restraints to keep the patient centered on the bed while turning to a significant angle from the prone position. In practice, the range of motion in the TriaDyne is generally limited to no more than 30 degrees to the left and right of prone. The Centers for Disease Control (“CDC”) defines kinetic therapy as lateral rotation of greater than 40 degrees to the horizontal left and right, or an arc of at least 80 degrees.

Moreover, the TriaDyne and many other beds are not capable of rotation beyond 62 degrees from even the supine position, much less so from the prone position, because the beds lack restraints to hold the patient on the bed. It is the belief of the inventors that further therapeutic benefits could be obtained by rotating patients to angle limits beyond 62 degrees in either direction, to, for example, 90 degrees or more in either direction, in order to recruit further areas of a collapsed lung to participate in gas exchange, and also to further reduce pressure on the dorsal regions of the patient's body. Accordingly, there is a need for a therapeutic bed that can automatically rotate a patient from the supine to the prone position and back, and that is capable of providing kinetic therapy (i.e., with an arc of at least 80 degrees) while still securing the patient to the center of the bed.

Another type of prone positioning bed comprises a base frame, a patient support platform rotatably mounted on the base frame for rotational movement about a longitudinal rotational axis of the patient support platform, and a drive system for rotating the patient support platform on the base frame. Such therapeutic beds are described in international patent applications having publication numbers WO 97/22323 and WO 99/62454. This type of bed is particularly advantageous for the treatment of patients with severe respiratory problems. Preferably, as described in publication number WO 99/62454, each end of the bed has a central opening at or near the longitudinal rotational axis of the patient support platform for efficiently managing the numerous patient care lines that are generally necessary for treating a patient on the patient support platform.

In the therapeutic bed of WO 99/62454, the central opening for receiving patient care lines at the head of the bed is provided by a continuous upright end ring, which also serves as a means for rotatably mounting the patient support platform on rollers. One drawback of such an arrangement is that the continuous end ring obstructs access to the head of the patient. Additionally, the initial placement of a patient on the bed requires disconnection of all patient care lines, and to remove a patient care line from the end ring requires that one end of the patient care line be unplugged from either the patient or the piece of equipment to which the line is attached, which can be very inconvenient and may jeopardize the patient, depending on the particular condition of the patient.

To retain a patient on the patient support platform in the prone position, the bed of WO 99/62454 has a pair of side rails fixedly mounted to the patient support platform in an upright position using stanchions and complementary sockets. A plurality of patient support packs are pivotally mounted on the side rails, and associated straps are buckled over the patient to hold the patient in place. Although the patient support packs may be flipped to the outside of the bed to uncover the patient in the supine position, the side rails remain upright and thus obstruct access to the patient in the supine position. To improve access to the patient in the supine position, it would be desirable to be able to move the side rails completely out of the way without removing them from the bed. Also, it would be advantageous to have a reliable way to ascertain whether the straps that buckle over the patient are properly tensioned to support the patient prior to moving the patient to the prone position.

One of the problems in the art of prone positioning therapeutic beds is to provide electrical connections to the bed for both the power and controller equipment that moves the bed and for the patient monitoring systems on the bed. To allow unrestricted rotation of the bed of WO 99/62454, electrical power has been provided by wire brushes at the interface between the rotating part of the bed and the nonrotating part of the bed. However, due to vibration and other abrupt movements, such wire brushes cause problems of electrical intermittence, which can be detrimental to the therapy of the patient. A direct, wired electrical connection would be preferable to eliminate such intermittence, provided that the wired electrical connection is capable of articulation during movement of the rotating part of the bed into the prone position.

Another problem in the field of prone positioning beds is to sufficiently support the head of a patient during rotation. In the past, elastic straps have been stretched across the patient's head to secure the head to the patient support platform. However, such straps are generally uncomfortable for the patient and do not provide sufficient lateral support for the patient's head. Additionally, such straps do not provide sufficient adjustability. It would be a significant improvement to provide a comfortable, adjustable head restraint that supports the patient's head both laterally and vertically.

Typically, prone positioning beds have lateral support pads for supporting the sides or legs of the patient during rotation. It is known in the art for such lateral support pads to be laterally adjustable. For purposes of rotational stability, it is desirable for the patient to be centered on the patient support platform. Therefore, it would be an advancement in the art to provide adjustable lateral support pads that automatically center the patient on the patient support platform. In conjunction with automatically centering lateral support pads, it would also be an advancement to provide symmetric leg abductors.

As mentioned above, prone positioning beds preferably have a drive system for rotating the patient support platform on the base frame. However, such drive systems generally prevent manual rotation of the patient support platform by medical personnel. If a patient develops an emergency condition, such as the need for CPR, while the bed is in a position other than the supine position, the drive system must be used to rotate the bed back to the supine position before administering appropriate care to the patient. Because the drive systems are subject to mechanical and electrical failures, it would be advantageous to provide a back-up means for quick, manual rotation of the patient support platform in emergency conditions.

Prone positioning beds also preferably have a locking mechanism to lock the patient support platform in a desired rotational position. One known locking mechanism comprises a lock pin longitudinally mounted in the base frame that is insertable into a corresponding hole on the patient support platform. However, such lock pins may be jostled loose under the influence of vibration and other abrupt movements of the bed. It would be an improvement to provide a means to prevent accidental disengagement or locking of the lock pin.

It is also known in the art of prone positioning beds to provide a sensor for determining and controlling the rotational position of the patient support platform. As taught in WO 99/62454, the rotational position of the patient support platform may be monitored and controlled by a rotary opto encoder of the type described therein. However, such a rotary opto encoder is fairly cumbersome and must be reinitialized by moving to an index location in the event of power interruptions. It would be more desirable to provide a simple and reliable sensor that determines angle positioning relative to a fixed reference to control the rotational position of the patient support platform.

Medical personnel often consider it valuable to monitor a patient's weight during the course of medical treatment. Many hospital beds have been designed and used that include weight scales to detect the combined weight of a patient and any accessories or equipment placed on the bed. Many of these beds sum the outputs of three or more load cells in analog and convert the summed analog signal to a digital value to detect the total weight borne by the load cells. Load cells, however, can malfunction, especially if they have experienced significant vibration or shock during transportation. However, it is difficult to detect when only one out of four or more load cells is malfunctioning if only the combined output is measured. Accordingly, there is a need for a weight monitoring system that evaluates the output of each load cell to detect malfunctioning load cells.

Because different doctors may develop different preferences for certain therapy settings, there is also a need for memory capabilities that enable medical personnel to program a course of therapy and to store it in memory for later retrieval and use. Because research studies on the benefits of kinetic therapy, prone positioning, or a combination of the two need to be based upon a consistent, pre-defined study-wide therapy protocol, there is a need for a data input interface that allows researchers to import a predefined protocol for operating the bed. Because it is important to monitor and record the effect that a course of kinetic, prone, or supine therapy, or some combination of them, has on a patient's condition, there is also a need for a data output interface for relaying or permanently recording the course of therapy given to a patient. These are all long-felt needs that have been unmet or insufficiently met by prior art devices.

Through research and innovation, the inventors overcame numerous other challenges in developing the present invention. To prevent an operating system crash from causing unplanned rotation of the bed, which could be dangerous if a patient is not adequately secured, a redundant hardware and software design is needed so that no single hardware or software failure will result in a condition that would be harmful to the patient. There is also a need for a therapeutic bed that has a suitable user interface for operating, monitoring, and standardizing its various functions.

SUMMARY OF THE INVENTION

A therapeutic bed in accordance with the present invention is directed to solving the aforementioned problems. The bed is a prone positioning bed comprising a base frame, a patient support platform rotatably mounted on the base frame for rotational movement about a longitudinal rotational axis of the patient support platform, and a drive system for rotating the patient support platform on the base frame. The surface of the patient support platform is comprised of one or more honeycomb composite core panels, a lightweight yet strong material that is also radiolucent. A fan may be mounted on the patient support platform proximate the foot end ring to provide ventilation to a patient's legs. A camera may also be mounted on the patient support platform proximate the head end ring to capture images of a patient's face.

An upright end ring at the head end of the bed is split into an upper section and a lower section. The upper section is removable from the lower section to allow improved access to the head of the patient and to allow placement or removal of the patient from the bed by removal of patient care lines from the end ring without removing the patient care lines from the patient or the equipment to which the lines are attached. A slotted wheel may be used as an alternative to the upright end ring, where the wheel has an outer perimeter, a center, and a slot extending from the outer perimeter to the center for routing patient care lines. Likewise, at the foot end of the bed, an opening is provided that is of sufficient size to permit passing of various patient connected devices, such as foley bags, through the opening without disconnecting the devices from the patient.

The therapeutic bed is mounted on the base frame by placing the upright end rings on a plurality of rollers rotatably mounted on a plurality of respective axles protruding from the base frame. To account for minor tolerances in the manufacturing and assembly of the patient support platform or base frame, all but one of the rollers is laterally slidable along its respective axle.

Additionally, the bed is provided with pivotally mounted side rails that may be folded neatly out of the way underneath the patient support platform for improved access to the patient in the supine position. Straps are provided to secure the opposing side rails over the patient before rotation into the prone position. Preferably, a pressure-sensitive tape switch is mounted on the patient support platform adjacent each side rail. When the side rail straps are properly tensioned, the side rails engage the tape switches, which allows the patient support platform to be rotated into the prone position. Alternatively, the straps that secure the opposing side rails over the patient may be connected to the patient support platform with tension-sensitive strap connectors that provide an indication of whether the straps are sufficiently tensioned before the patient is rotated into the prone position. The tension-sensitive strap connectors provide both a visual indication and an electrical signal that may be used by a controller to control the rotation of the patient support platform.

The present invention also incorporates a direct, wired electrical connection to the patient support platform while still allowing full rotation of the patient support platform in either direction. The necessary electrical wires are housed within a chain-like cable carrier that is disposed within an annular channel attached to the patient support platform. An annular cover is installed adjacent the annular channel to retain the cable carrier within the annular channel, but the annular cover is not attached to the annular channel. Rather, the annular cover is attached to the nonrotating part of the bed. One end of the cable carrier is attached to the annular channel, and the other end is attached to the annular cover. The length of the cable carrier is sufficient to allow a full 360 degrees rotation of the patient support platform in either direction from 0 degrees supine flat while maintaining a direct electrical connection.

More preferably, the direct, wired electrical connection to the patient support platform may be provided with a flexible printed circuit board (PCB) in lieu of a chain-like cable carrier. The flexible PCB resides within an annular channel attached to the patient support platform, and an annular cover is fastened to a flange of the annular channel such that a gap exists between the annular channel and the annular cover around the outer periphery. One end of the flexible PCB is attached to the annular channel, which provides power and electrical signals to the rotating part of the bed, and the other end of the flexible PCB passes through the gap between the annular channel and the annular cover and is connected to the electrical apparatus on the nonrotating part of the bed. Like the cable carrier mentioned above, the flexible PCB has a length sufficient to allow a full 360 degrees rotation of the patient support platform in either direction while maintaining a direct electrical connection between the nonrotating and rotating parts of the bed. To ensure that the wired electrical connection is not articulated beyond its physical limit as a result of manually rotating the bed in the emergency backup mode, a mechanical stop is provided to limit rotation of the patient support platform to about 365 degrees. Sensors are provided to detect activation of the mechanical stop.

A pair of adjustable head restraints are provided for the therapeutic bed. Each head restraint, which is slidably mounted on transverse rails of the patient support platform, includes a clamping mechanism that fixes the position of the head restraint both vertically and laterally through the operation of a single lever. Each head restraint includes a pad that comfortably supports the front and side of the patient's head.

As an alternative to the pair of adjustable head restraints, a head restraint apparatus is provided comprising a casing having a closed bottom end, an open top end, and an open front end. The casing, which is configured to substantially encompass the back and sides of a person's head, encloses a cavity for receiving a person's head resting in a supine position. A face piece configured to restrain at least a portion of the front of a person's head is also provided for removable attachment to the top end of the casing. Optionally, the casing comprises left and right side members hingedly connected to a headrest member, so that a patient's head can easily be placed on and removed from the casing by swinging the right and left side members outwardly from the casing. Openings are also provided in the right and left sides of the casing to provide access to a patient's ears.

The casing may be pivotally mounted on a gas strut in order to enable limited movement of the head of a person being laterally rotated on the therapeutic bed. The casing may also be mounted on a guide member that mounts the casing to the bed and provides adjustable lateral and longitudinal positioning of the casing with respect to the bed.

A therapeutic bed in accordance with the present invention further includes a pair of symmetrically mounted lateral support pads or adductors that serve to automatically center the patient on the patient support platform. The lateral support pads are symmetrically mounted to a threaded rod that is transversely mounted to the patient support platform. The threaded rod has right-hand threads on one side and left-hand threads on the other side. One of the lateral support pads is mounted to the right-hand threaded portion of the threaded rod, and the other lateral support pad is mounted to the left-hand threaded portion of the threaded rod. By rotating the threaded rod in the desired direction, the lateral support pads may be moved symmetrically toward or away from the patient. Similarly, a preferred bed also includes a pair of leg abductors that are mounted with a threaded rod in like manner as the lateral support pads.

A motor and shaft brake are provided to safely drive the therapeutic bed of the present invention. The brake engages and impedes rotation of the motor's shaft unless power is supplied to the brake. Therefore, if there is a fault in the system providing power to the therapeutic bed, the brake will arrest movement of the patient support platform.

The present therapeutic bed also preferably has a quick release mechanism for manually disengaging the patient support platform from the drive system. The quick release mechanism preferably comprises a manually operable lever and linkage that cooperate to push and pull a shaft to which a roller is mounted. The roller may thus be brought into or out of engagement with the belt of the drive system. When the roller is disengaged from the drive belt, the patient support platform may be manually rotated, which is useful in emergency conditions such as CPR.

The present bed further includes a lock pin mounted to the base frame that is insertable into a cooperating hole of a locking ring on the patient support platform to mechanically prevent rotation of the patient support platform. Preferably, the lock pin assembly incorporates a detent and a pair of proximity switches that indicate the position of the lock pin with respect to the locking ring and electrically control whether the patient support platform is allowed to rotate. The lock pin may be twistable to engage a protrusion on the lock pin with the patient support platform and thereby prevent retraction of the pin from its locked position.

The present invention also preferably includes an electrical angle sensor mounted to the patient support platform. A preferred angle sensor comprises an inclinometer that is sensitive to its position with respect to the direction of gravity. The output signal from the angle sensor may be calibrated for a controller of the drive system to control the rotational position of the patient support platform.

The present invention also preferably has a computer to operate the motor control circuitry in accordance with control signals received over a parallel cable from a computer mounted to the therapeutic bed. To prevent operating system crashes from causing the motor to operate unexpectedly by freezing the bits on the parallel cable, the motor control circuitry is preferably configured to require a code to be emitted by the computer over a separate serial bus to enable the motor control circuitry to operate the motor.

The present invention also preferably includes a weight monitoring system using a plurality of; load cells and circuitry (which may include computer hardware and software) capable of detecting failures in any one of the load cells. Each load cell produces an analog electrical output corresponding to a load borne by the load cell. The circuitry converts the analog electrical outputs of each of the load cells into a digital signal, and only then sums the digital signals together to calculate at least a portion of the bed's weight. The circuitry further comprises memory for storing a patient's weight trend data, calibration functions for determining the tare weight of the bed, a data entry function for entering a patient's weight, and means for displaying a patient's weight trend data.

A monitoring circuit is provided for the therapeutic bed to compute the total time a patient spent in kinetic therapy, prone kinetic therapy, prone kinetic therapy over an arc of at least 80 degrees, supine kinetic therapy, and supine kinetic therapy over an arc of at least 80 degrees.

A touch screen user interface is provided to monitor and control the operations of the therapeutic bed. The touch screen user interface guides a caregiver through a set of procedures for the caregiver to perform before rotating the patient support platform to the prone position. The user interface also provides programmable left angle limits, right angle limits, and a plurality of dwell times for a course of kinetic therapy. Alternatively, therapy settings can be imported through a data import interface and selected on the touch screen user interface. The touch screen interface also provides an emergency CPR button that, when selected, lowers both ends of the patient support platform and rotates it to the supine position. The touch screen interface also provides a hidden lockout button that, when selected, causes at least a portion of the touch screen interface to become nonresponsive to touch until a code is entered. The touch screen user interface also provides a data screen to display diagnostic information based upon readings from the plurality of sensors.

The therapeutic bed of the present invention is capable of rotating a patient from the supine position to the prone position and providing kinetic therapy in the prone position through an arc of rotation of up to approximately 730 degrees. Preferably, the patient support platform rotates at an angular velocity of no more than two degrees per second.

It is an object of the present invention to provide a therapeutic bed having a split end ring or slotted wheel at the head of the bed for improved access to the head of a patient lying on the bed and for placement or removal of the patient from the bed without disconnecting patient care lines from the patient.

It is another object of this invention to provide an opening at the foot of the bed having sufficient size to permit passing of patient connected devices, such as foley bags, through the opening without disconnecting the devices from the patient.

It is a further object of the present invention to provide a therapeutic bed having side rails that fold underneath the patient support platform of the bed for improved bedside access to the patient.

It is yet another object of this invention to provide a therapeutic bed with patient retaining straps having strap connectors that indicate whether the straps are sufficiently tensioned.

It is another object of the present invention to provide a therapeutic bed with side rails that are engageable with pressure-sensitive tape switches mounted to the patient support platform to indicate whether the straps on opposing side rails are properly tensioned.

It is still another object of this invention to provide a prone positioning therapeutic bed having a direct, wired electrical connection between the rotating part of the bed and the nonrotating part of the bed.

It is yet another object of this invention to mechanically limit rotation of the bed in either direction to one full 360° turn plus about 50, and to electrically detect when one full turn has been reached.

It is a further object of this invention to provide a prone positioning therapeutic bed having a flexibly mounted head restraint apparatus to maintain proper patient alignment.

It is yet another object of this invention to provide a therapeutic bed having a pair of symmetrically mounted lateral support pads that serve to automatically center the patient on the patient support platform.

It is still another object of this invention to provide a prone positioning therapeutic bed with a patient support platform, a drive system for rotating the patient support platform, and a quick release mechanism for manually disengaging the patient support platform from the drive system to allow manual rotation of the patient support platform.

Another object of this invention is to provide a prone positioning therapeutic bed having a lock pin for mechanically preventing rotation of the patient support platform as desired.

Still another object of this invention is to provide a prone positioning therapeutic bed having a lock pin with cooperating proximity switches for electrically preventing rotation of the patient support platform as desired.

A further object of this invention is to provide a rotating therapeutic bed having a lock pin that is twistable to prevent disengagement of the lock pin.

Yet another object of this invention is to provide a therapeutic bed having a rotatable patient support platform with gravity-sensitive angle sensors for controlling the rotation of the patient support platform and for determining the longitudinal (Trendelenburg) angle of the patient surface.

Another object of this invention is to provide a therapeutic bed with foam having semi-independent pressure relieving pillars.

Still another object of this invention is to provide a user-friendly touch screen interface to control and monitor the operation of the therapeutic bed.

Further objects of this invention are to provide a system for monitoring a patient's weight over time, detecting malfunctioning load cells, providing programmable therapy settings, and maintaining a log of past therapy provided.

Further objects and advantages of the present invention will be readily apparent to those skilled in the art from the following detailed description taken in conjunction with the annexed sheets of drawings, which illustrate the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a perspective view of a therapeutic bed in accordance with the present invention.

FIG. 2

is a perspective view of the head portion of the therapeutic bed of

FIG. 1

looking toward the foot of the bed.

FIG. 2A

is a perspective view of an alternative head restraint for the therapeutic bed of FIG.

1

.

FIG. 2B

illustrates a slotted wheel that can be used as an alternative to the end rings of FIG.

2

.

FIG. 3

is a perspective view of the head portion of the therapeutic bed of

FIG. 1

looking toward the head of the bed.

FIG. 3A

is an exploded perspective view of the clamping mechanism for the head restraints of the therapeutic bed of FIG.

1

.

FIG. 4

is a perspective view of a side rail of the therapeutic bed of FIG.

1

.

FIG. 4A

is a perspective view of the detent for the side rail of FIG.

4

.

FIG. 5

is a side elevational view of a strap connector for the side rail of FIG.

4

.

FIG. 6

is a rear elevational view of the strap connector of FIG.

5

.

FIG. 7

is a perspective view of the therapeutic bed of

FIG. 1

showing symmetric lateral support pads and leg abductors.

FIG. 8

is a perspective view of the foot portion of the therapeutic bed of

FIG. 1

looking toward the foot of the bed.

FIG. 9

is a front elevational view of a portion of FIG.

8

.

FIG. 10

is a front elevational view of the rotation limiter of the therapeutic bed of

FIG. 1

shown in a position of maximum negative rotation.

FIG. 11

is a front elevational view of the rotation limiter of the therapeutic bed of

FIG. 1

shown in a position of maximum positive rotation.

FIG. 12

is a perspective view of the foot portion of the therapeutic bed of

FIG. 1

looking toward the head of the bed.

FIG. 13

is a rear elevational view of the therapeutic bed of FIG.

1

.

FIG. 14

is a perspective view of the quick release mechanism for the drive system of the therapeutic bed of FIG.

1

.

FIG. 15

is a perspective,view looking up at a side rail folded under the patient support platform of the therapeutic bed of FIG.

1

.

FIG. 16

is a side elevational view of a side rail and cooperating tape switch on a therapeutic bed in accordance with the present invention.

FIG. 17

is a cross-sectional view of the tape switch of FIG.

16

.

FIG. 18

is a rear elevational view of a flexible PCB disposed within an annular channel of a therapeutic bed in accordance with the present invention.

FIG. 19

is a cross-sectional view of the flexible PCB and annular channel of FIG.

18

.

FIG. 20

is an enlarged cross-sectional view of the flexible PCB of FIG.

18

.

FIG. 21

is a top view of a lock pin assembly for a therapeutic bed in accordance with the present invention.

FIG. 22

is a perspective view of an alternative lock pin assembly for the therapeutic bed of FIG.

1

.

FIG. 22A

is a side view of the lock pin assembly of FIG.

22

.

FIG. 23

is a block diagram of a system that brakes the movement of a motor shaft in one embodiment of a system that controls rotation of a patient support platform of the therapeutic bed of FIG.

1

.

FIG. 24

is a block diagram illustrating one embodiment of a redundant hardware and software configuration for operating the motors of the therapeutic bed of FIG.

1

.

FIG. 25

is a perspective view of an alternative head restraint apparatus for the therapeutic bed of FIG.

1

.

FIG. 26

is another perspective view of the alternative head restraint apparatus of FIG.

25

.

FIG. 27

is a perspective view of a face piece for the alternative head restraint apparatus of FIG.

25

.

FIG. 28

is a perspective view of a slidable mount apparatus for the alternative head restraint apparatus of FIG.

25

.

FIG. 29

is a top view illustrating the use of honeycomb composite core panels to provide a radiolucent surface for the patient support platform

20

of FIG.

1

.

FIG. 30A

is a perspective view of a floating roller used to guide the upright end rings of FIG.

12

.

FIG. 30B

is a side view of the floating roller of FIG.

30

A.

FIG. 31

is a block diagram illustrating a weight monitoring system for one embodiment of a therapeutic bed in accordance with the present invention.

FIG. 32

is a flowchart illustrating a button-operated CPR function built into one embodiment of the therapeutic bed of the present invention.

FIG. 33

is a block diagram illustrating an embodiment of the programmable therapy setting functionality of the therapeutic bed of the present invention.

FIG. 34

is a block diagram illustrating one embodiment of the therapy logging functionality of the therapeutic bed of the present invention.

FIG. 35

illustrates one embodiment of a home screen of a touch screen interface used to monitor and control various functions of the therapeutic bed of FIG.

1

.

FIG. 36

illustrates a prone checklist screen of the touch screen interface of FIG.

35

.

FIG. 37

illustrates a prone therapy settings screen of the touch screen interface of FIG.

35

.

FIG. 38

illustrates a scale functions screen of the touch screen interface of FIG.

35

.

FIG. 39

illustrates a weight trend screen of the touch screen interface of FIG.

35

.

FIG. 40

illustrates a bed height/tilt screen of the touch screen interface of FIG.

35

.

FIG. 41

illustrates a supine park angle screen of the touch screen interface of FIG.

35

.

FIG. 42

illustrates a therapy meters screen of the touch screen interface of FIG.

35

.

FIG. 43

is a functional flow diagram of the touch screen interface of

FIGS. 35-42

.

FIG. 44

illustrates a retrievable data matrix stored in memory for one embodiment of the therapeutic bed of FIG.

1

.

DETAILED DESCRIPTION

Referring to

FIGS. 1 and 2

, a therapeutic bed

10

in accordance with the present invention preferably comprises a ground engaging chassis

12

mounted on wheels

14

. A base frame

16

is mounted on chassis

12

with pivot linkages

18

. Rams

15

,

17

housed within base frame

16

cooperate with pivot linkages

18

to form a lift system to raise and lower base frame

16

on chassis

12

. A patient support platform

20

having upright end rings

22

,

24

is rotatably mounted on base frame

16

with rollers

26

such that patient support platform

20

may rotate about a longitudinal axis between a supine position and a prone position. Mattress or foam padding (not shown for clarity), such as the type described in co-pending and commonly assigned application for Letters Patent Ser. No. 09/588,513 filed Jun. 6, 2000, entitled “MATTRESS WITH SEMI-INDEPENDENT PRESSURE RELIEVING PILLARS INCLUDING TOP AND BOTTOM PILLARS,” which is incorporated herein by reference, overlays patient support platform

20

.

Side support bars

28

,

30

extend between end rings

22

,

24

. At the head of bed

10

, a guide body

32

having a plurality of slots

34

for routing patient care lines (not shown) is slidably mounted on rails

36

with support rod

31

. Similarly, at the foot of bed

10

, a central opening

118

is provided for receiving a removable patient care line holder (not shown) having a plurality of circumferential slots for routing patient care lines.

Central opening

118

is preferably of sufficient size to allow passing of patient connected devices, such as foley bags (not shown), through the central opening

118

without disconnecting such devices from the patient. For such purposes, central opening

118

is preferably as large as possible, provided that strength and configuration requirements of the bed are maintained. More particularly, the inner diameter of central opening

118

is preferably at least eight inches, more preferably, at least about 12 inches, in diameter. The foregoing basic structure and function of bed

10

is disclosed in greater detail in international application number PCT/IE99/00049 filed Jun. 3, 1999, which is incorporated herein by reference.

Still referring to

FIG. 1

, bed

10

preferably comprises one or more folding side rails

62

pivotally mounted to patient support platform

20

to assist in securing a patient to support platform

20

before rotation into the prone position. As further described below in connection with

FIG. 15

, side rails

62

fold underneath platform

20

for easy access to a patient lying atop cushions

21

a

,

21

b

,

21

c

in the supine position. Bed

10

also preferably has a head rest

50

and a pair of head restraints

48

, which are described in more detail below in connection with FIG.

3

. Although not shown for the sake of clarity, a fan may be mounted on the patient support platform

20

near the end ring

24

at the foot of bed

10

to ventilate a patient's legs.

As shown in

FIG. 2

, end ring

22

at the head of bed

10

is split into two sections for improved access to a patient lying on bed

10

. Upper section

22

a

is removable from lower section

22

b

. Upper section

22

a

has a pair of shafts

40

that are inserted into vertical stabilizer tubes

38

in the closed position. Likewise, tabs

46

on upper section

22

a

mate with tubular openings on lower section

22

b

. Latches

44

secure upper section

22

a

to lower section

22

b

in the closed position. When latches

44

are unlatched, upper section

22

a

may be raised, pivoted about the vertical axis of one of the shafts

40

, and left in an open position supported by one of the shafts

40

in corresponding stabilizer tube

38

. Alternatively, upper section

22

a

may be removed entirely. In either case, upper section

22

a

may be moved out of the way for unobstructed access to the patient and manipulation of patient care lines. An alternative to a split end ring is to provide a slotted wheel

41

(

FIG. 2B

) having a radial slot

43

supported by a plurality of rollers

42

. Patient care lines would be inserted or removed from the center of wheel

41

through slot

43

. As another alternative to a split end ring, patient support platform

20

could be cantilevered from the base frame at one end of the bed, but such a configuration would be extremely heavy.

One of the key challenges in patient proning is adequately supporting the head in a manner that facilitates proper alignment of the patient's vertebrae in both the prone and supine positions, as well as at all angular positions of rotation. Other challenges include minimizing the risk of skin, face, and ear abrasions and avoiding entanglement or kinking of patient care lines to the patient's head, throat, or face.

Referring now to

FIGS. 3 and 3A

, head restraints

48

are slidably mounted to transverse support rails

58

,

60

on guides

54

with mounting arms

52

. For the sake of clarity, only one head restraint

48

is shown in

FIGS. 2 and 3

. Each guide

54

has a clamp

56

that is manually operable by a handle

56

a

and serves to secure each guide

54

in a desired lateral position as further described below. Mounting arms

52

are slidably mounted in holes

56

h

of bosses

56

b

to provide vertical positioning of head restraints

48

. Handle

56

a

is attached to a drum

56

f

that is rotationally mounted to flanges

54

a

of guide

54

by shaft

56

g

which is disposed within hole

56

d

of drum

56

f

. Drum

56

f

has a ramp

56

c

for engaging one of the flanges

54

a

, and hole

56

d

is offset from the central axis of drum

56

f

to form a cam

56

e

. Movement of handle

56

a

in the appropriate direction causes ramp

56

c

to engage one of the flanges

54

a

and thereby spread flanges

54

a

apart slightly, which causes one of the flanges

54

a

to frictionally engage mounting arm

52

and thereby fix the vertical position of head restraint

48

. Simultaneously, such rotation of handle

56

a

causes cam

56

e

to frictionally engage one of the transverse support rails

58

,

60

and thereby fix the lateral position of head restraint

48

. Thus, clamps

56

simultaneously provide both lateral and vertical positioning of head restraints

48

, which have pads

48

a

for comfortably engaging the front and sides of the head of a patient whose head is resting on head rest

50

. Head rest

50

may be mounted to transverse support rails

58

,

60

or to pad

21

a

. Head restraints

48

thereby provide increased stability and comfort for a patient when bed

10

is rotated to the prone position.

Although not shown for the sake of clarity, a camera for taking images of a patient's face may optionally be mounted over or proximate to the head restraints

48

using another guide and mounting arm slidably mounted on transverse support rails

58

,

60

. Providing a camera would help medical personnel monitor the effect of kinetic therapy on a patient from a remote location.

If a particular patient requires only partial rotation for therapy such that patient support platform

20

need not be rotated beyond about, for example, 30 degrees in either direction, alternative head restraints

248

as shown in

FIG. 2A

may be mounted in clamps

56

using mounting arms

252

in like manner as head restraints

48

. Alternative head restraint

248

is designed to provide lateral support for the patient's head in instances when the patient will not be rotated into the prone position such that vertical restraint of the head is not required.

FIGS. 25 through 28

illustrate portions of another alternative head restraint apparatus

348

that permits the head to rest dependent over a greater surface area in order to lessen the risk of pressure sores and abrasions. The head restraint apparatus

348

comprises a U-shaped casing

350

that supports a patient's head in both supine and lateral positions and a face piece

380

that supports a patient's head in the prone position. The casing

350

comprises, at its base, a headrest member

3152

and two upright side members

354

and

356

. Preferably, the two upright side members

354

and

356

are connected to the headrest member

352

with hinges

368

so that, as illustrated in

FIG. 26

, side members

354

and

356

can be swung outwardly to facilitate easy positioning and transport of a patient on or off the patient support platform

20

and casing

350

. Cushions

358

, such as foam or gel pads, line the inside of casing

350

. An additional neck support cushion

359

is provided to support the neck of a patient in the supine position. Straps

364

with adjustable buckles

366

connected to side members

354

are provided to secure the face piece

380

to the top of the patient's head.

The face piece

380

comprises foam or cushion material supported by a flexible plastic plate, which allows the foam to more fully contour to the patient's head. The face piece

380

has one or more apertures

382

for the nose and mouth, and optionally also the mouth. For the sake of simplicity, the face piece

380

is shown substantially flat, but preferably, the face piece is contoured so that the weight of the head in the prone position will be distributed over a large surface area of the face piece

380

. Straps

384

terminating in clasps

386

descend from sides of the face piece, for mating with adjustable buckles

366

of strap connectors

364

.

After resting a patient's head on the headrest member

352

, the face piece

380

is fitted over the patient's forehead. Clasps

384

are mated with buckles

366

and the strap

364

is tightened to tightly fit a patient's head between the casing

350

and the face piece

380

.

One embodiment of casing

350

incorporates relatively short upright side members

354

and

356

. In a preferred embodiment, the upright side members

354

and

356

are elongated to prevent a patient's head from tending to push out of the casing and into straps

364

and

384

when the patient is rotated into a substantially lateral position. Also preferably, side members

354

and

356

further comprise apertures

362

to provide ventilation and access to the ears of a patient.

To facilitate patient placement on or off the patient support platform

20

, the headrest portion

352

of the casing

350

is mounted on a swiveling shaft

360

. The swivel feature enables the casing

350

to rotate in the horizontal plane toward one of the sides of the patient support platform

20

.

When a patient is rotated from the prone to the supine position, the patient's weight will cause the patient to sink into the proning cushions

64

and away from the patient support platform

20

. To maintain proper spinal column alignment, the head should be allowed to descend with the rest of the patient's body as the patient is rotated into the prone position. Accordingly, in one embodiment the swiveling shaft

360

is coupled to the patient support platform

20

through a mounting block

357

. The shaft

360

slides up and down with respect to the mounting block

357

as gravity dictates. Furthermore, a flexible mount

361

, preferably made of rubber, couples the casing

350

to the swiveling shaft

360

. The ability of the swiveling shaft

360

to slide up and down with respect to mounting block

357

, and the flex provided by the flexible mount

361

, both help maintain proper alignment of the patient's spinal column while the patient is in the prone position and during kinetic therapy. In addition, spring (not shown) can be used to resist movement of the swiveling shaft

360

with respect to the mounting block

357

. Alternatively, a gas strut (not shown) mounted directly to the patient support platform

20

or a slidable mount apparatus may be used in place of the swiveling shaft

360

and mounting block

357

. A further alternative to the swiveling shaft

360

and mounting block

357

is a lead screw assembly that facilitates gradual vertical adjustment of the casing

350

between two defined vertical positions.

Referring now to

FIG. 28

, a slidable mount apparatus

400

is provided to connect the casing

350

to the patient support platform

20

. The slidable mount apparatus comprises lateral guides

402

slidably mounted on transverse support rails

58

(FIG.

3

). Lateral guides

402

carry longitudinal support rails

410

on which longitudinal guides

412

are slidably mounted. A head restraint mounting platform

412

, to which the swiveling shaft

361

(

FIG. 25

) or mounting block

357

(not shown in

FIG. 28

) is attached, bridges longitudinal guides

412

together. The slidable mount apparatus

400

provides limited movement of the head restraint apparatus

348

in both the “x” and “y” directions along a plane substantially parallel to a patient support surface of the bed.

FIGS. 4 and 15

illustrate a preferred structure and operation of folding side rails

62

. Preferably, four independently operable side rails

62

are pivotally mounted on each side of bed

10

. For each side rail

62

, main rail

66

is slidably mounted on shaft

80

with mounting cylinders

82

. Shaft

80

has a slot

80

a

for receiving guides such as set screws

83

installed in holes

82

a

of mounting cylinders

82

. Preferably, set screws

83

are not tightened against slot

80

a

but simply protrude into slot

80

a

to prevent side rail

62

from rotating with respect to shaft

80

. In that regard, set screws

83

could be replaced with unthreaded pins. When set screws

83

are loosened, side rail

62

is free to slide longitudinally along shaft

80

for proper positioning with respect to the patient. When set screws

83

are tightened, side rail

62

is fixed with respect to shaft

80

. Shaft

80

is rotatably mounted to side support bar

28

,

30

with rail mounts

78

. Pivot link

68

is hinged to main rail

66

with hinge

72

, and cushion

64

is hinged to pivot link

68

with hinge

70

, which has a hinge plate

70

a

for attaching cushion

64

. Side rails

62

are thus capable of folding under patient support platform

20

as shown in

FIG. 15

, which is a view looking up from beneath patient support platform

20

. A strap

174

with one end secured around shaft

80

may be provided to retain cushion

64

in the folded under position with mating portions of a snap respectively provided on cushion

64

and strap

174

. A pair of straps

74

and an adjustable buckle

76

are provided to fasten each opposing pair of side rails

62

securely over the patient. One end of strap

74

is secured to side support bar

28

with a strap connector

88

, which is slidably mounted in slot

28

a

of side support bar

28

. When strap

74

is properly secured with the appropriate tension using buckle

76

, tabs

160

on strap connector

88

are sandwiched between main rail

66

and side support bar

28

, which further helps to prevent longitudinal movement of side rail

62

. Side rails

62

thus serve to hold the patient securely in place as bed

10

is rotated into the prone position, and side rails

62

fold neatly out of the way for easy access to the patient in the supine position.

As best illustrated in

FIG. 4A

, an indexed disc

86

is preferably provided on one end of shaft

80

for cooperation with a pull knob

84

to form a detent that holds side rail

62

in one or more predetermined rotational positions. To that end, disc

86

preferably has one or more recesses

228

for receiving a pin

84

a

which is manually operated by pull knob

84

. Pull knob

84

is fixedly mounted to rail mount

78

with boss

230

. Preferably, pin

84

a

is biased into engagement with disc

86

. By engaging one of the recesses

228

, pin

84

a

prevents rotation of shaft

80

and thereby functions as a detent to hold side rail

62

in a predetermined rotational position. Side rail

62

may be moved to a different predetermined rotational position by pulling knob

84

sufficiently to disengage pin

84

a

from the given recess

228

so that shaft

80

is free to rotate. Preferably, one of the predetermined rotational positions of side rail

62

corresponds to the folded under position.

Referring now to

FIGS. 5 and 6

, each strap connector

88

comprises a tension-sensitive mechanism that provides both visual and electrical indications of whether strap

74

is properly secured over the patient. The following description describes the attachment of a strap connector

88

to side support bar

28

. It will be understood that strap connectors

88

may be similarly attached to side support bar

30

. Each strap connector

88

comprises a tension plate

90

that partially resides within a housing

96

. A cover plate

176

is attached to housing

96

by fasteners

182

inserted into holes

96

a

. Tabs

160

extend from housing

96

, and studs

178

protrude from tabs

160

as shown. Discs

180

are mounted to studs

178

with screws

183

. Slots

28

b

on the inner side of support bar

28

provide access for installation of screws

183

. Studs

178

are adapted to slide in slots

28

a

of side support bar

28

, and discs

180

serve to retain strap connector

88

on side support bar

28

. Tension plate

90

has a slot

92

to which strap

74

is attached and a central cut-out

93

that forms a land

100

. Inverted U-shaped channels

102

protrude from the back of housing

96

into central cut-out

93

of tension plate

90

. Land

100

of tension plate

90

cooperates with channels

102

of housing

96

to capture springs

98

which tend to force tension plate

90

downward toward lower edge

95

of housing

96

such that switch

104

is disengaged when strap

74

is slack. Switch

104

is connected to an electrical monitoring and control system (not shown) in a customary manner. When strap

74

is buckled and tightened sufficiently, the tension in strap

74

overcomes the biasing force of springs

98

, and tension plate

90

moves upward to engage switch

104

, which sends a signal to the electrical monitoring and control system indicating that strap

74

is properly tensioned. Preferably, the electrical monitoring and control system is programmed such that bed

10

cannot rotate until each strap

74

is properly tensioned to ensure that the patient will be safely secured in bed

10

as it rotates to the prone position. Additionally, tension plate

90

preferably has a tension indicator line

94

that becomes visible outside housing

96

when strap

74

is properly tensioned.

More preferably, as illustrated in

FIG. 16

, instead of utilizing tension-sensitive strap connectors

88

, a pressure-sensitive tape switch

234

may be installed to side support bars

28

,

30

adjacent each side rail

62

. Tape switch

234

is preferably of the type commonly available from the Tape Switch company. Strap

74

is attached to a crossbar

240

that spans main rails

66

. When strap

74

is properly tensioned, main rails

66

depress tape switch

234

, which sends a signal through electrical leads

238

to the monitoring and control system indicating that side rail

62

is properly secured over the patient. Preferably, the monitoring and control system is programmed such that the patient support platform

20

is not allowed to rotate into the prone position unless all side rails

62

have been properly secured as indicated by tape switches

234

. To help calibrate each tape switch

234

, a pad

236

may be attached to side support bars

28

,

30

below the tape switch

234

adjacent each side rail

62

. Pads

236

are made of a compressible material, such as rubber, having a suitable hardness and thickness so that, as strap

74

is buckled, main rails

66

will first compress pads

236

and then depress tape switch

234

when strap

74

is buckled to the appropriate tension.

FIG. 17

illustrates a preferred embodiment of tape switch

234

. A mounting bracket

242

, which is preferably made of extruded aluminum, houses two conductive strips

250

and

246

that are separated at their upper and lower edges by insulator strips

248

. Conductive strip

250

is a planar conductor oriented in a vertical plane as shown. Conductive strip

246

is installed under a preload such that it is bowed away from conductive strip

250

in its undisturbed position. Conductive strips

250

,

246

and insulator strips

248

are enclosed within a plastic shroud

244

. When main rails

66

engage tape switch

234

with sufficient pressure, conductive strip

246

is displaced to the position shown at

246

a

, which completes the circuit with conductive strip

250

and sends a signal through leads

238

indicating that the strap

74

is properly secured.

As shown in

FIG. 7

, bed

10

preferably comprises a pair of lateral support pads

116

for holding a patient in place laterally. Lateral support pads

116

are connected to mounts

108

, which are slidably mounted on transverse support rails

106

that span the gap between side support bars

28

,

30

. Mounts

108

are also threadably engaged with a threaded rod

112

, the ends of which are mounted in side support bars

28

,

30

with bearings

110

. Mounts

108

are symmetrically spaced from the longitudinal centerline of bed

10

. Preferably, another bearing

111

supports the middle portion of rod

112

, and a manually operable handle

114

is provided on at least one end of rod

112

. With respect to element

114

, the term “handle” as used herein is intended to mean any manually graspable item that may be used to impart rotation to rod

112

. Alternatively, rod

112

may be motor driven. One side

112

a

of rod

112

has right-hand threads, and the other side

112

b

has left-hand threads. By rotating handle

114

in the appropriate direction, lateral support pads

116

are symmetrically moved toward or away from the patient, as desired. Due to the symmetrical spacing of mounts

108

and the mirror image threading

112

a

,

112

b

of rod

112

, lateral support pads

116

provide for automatic centering of the patient on bed

10

, which enhances rotational stability. Similarly, leg abductors

184

having straps

186

for securing a patient's legs may be mounted to mounts

108

in like manner as lateral support pads

116

. The term “patient support accessory” is used herein to mean any such auxiliary equipment, including but not limited to lateral support pads and leg abductors, that is attachable to mounts

108

for the purpose of providing symmetric lateral support to a patient on bed

10

.

FIGS. 8 through 13

illustrate an apparatus at the foot of bed

10

for supplying a direct electrical connection between non-rotating base frame

16

and rotating patient support platform

20

. As best shown in

FIGS. 8 and 13

, end ring

24

, which is fastened to rotating patient support platform

20

, is also connected to an annular channel

126

that serves as a housing for a cable carrier

148

. Cable carrier

148

carries an electrical cable (not shown) comprising power, ground, and signal wires as is customary in the art. Channel

126

, which preferably has a C-shaped cross-section, may be attached to end ring

24

by way of support bars

192

. Because channel

126

is attached to end ring

24

, channel

126

rotates with patient support platform

20

. As shown in

FIGS. 12 and 13

, an annular cover

198

is connected to upright foot frame

144

, which extends upward from base frame

16

. Cover

198

is preferably mounted on a ring

196

with fasteners

200

, and ring

196

is preferably mounted to support bars

194

that extend from stiffeners

144

a

of foot frame

144

. Cover

198

, which is preferably made of metal to shield cable carrier

148

from radio frequency signals external of bed

10

, is positioned longitudinally adjacent channel

126

to retain cable carrier

148

within channel

126

, but cover

198

is not connected to channel

126

. Thus, channel

126

is free to rotate with end ring

24

, but cover

198

is stationary. One end

150

of cable carrier

148

is attached to channel

126

, and the other end

152

of cable carrier

148

is attached to cover

198

. The length of cable carrier

148

is preferably sufficient to allow patient support platform

20

to rotate a little more than 360 degrees in either direction. This arrangement provides a direct, wire-based electrical connection to the rotating part of bed

10

while still allowing a complete rotation of patient support platform

20

in either direction.

More preferably, as shown in

FIG. 18

, instead of cable carrier

148

, a flexible PCB

252

may be used to supply a direct electrical connection between non-rotating base frame

16

and rotating patient support platform

20

.

FIG. 18

is a view of a preferred embodiment in the same direction as

FIG. 13

, but

FIG. 18

shows only flexible PCB

252

and its channel

260

and cover

264

for the sake of clarity. Like channel

126

described above, channel

260

is basically C-shaped in cross-section as shown in FIG.

19

. However, channel

260

has an inner flange

258

to which cover

264

is attached, preferably with fasteners

262

. Flexible PCB

252

resides generally within channel

260

. A gap

266

exists between channel

260

and cover

264

through which one end of flexible PCB

252

may pass for attachment to non-rotating base frame

16

(not shown) at connection

256

. The other end

254

of flexible PCB

252

is attached to channel

260

, which is attached to rotating patient support platform

20

. Like cover

198

above, cover

264

is preferably made of metal to shield flexible PCB

252

from radio frequency signals external of bed

10

. As shown in

FIG. 20

, flexible PCB

252

comprises a plurality of flexible conductive strips

268

surrounded by a flexible insulator

270

. Conductive strips

268

carry signals or ground connections, as desired, and multiple flexible PCB's

252

may be used if necessary, depending on the number of signals required. Like cable carrier

148

above, flexible PCB

252

is preferably long enough to allow patient support platform

20

to rotate a little more than 360 degrees in either direction.

To prevent excessive rotation of patient support platform

20

and the attendant damage that excessive rotation would cause to cable carrier

148

or flexible PCB

252

and its enclosed electrical wires, a rotation limiter

128

is provided on the inner surface of upright foot frame

144

as shown in

FIGS. 8

,

10

, and

11

. Rotation limiter

128

is pivotally mounted on frame

144

at point

162

and comprises contact nubs

128

a

and

128

b

for engaging a boss

134

that protrudes from frame

144

. Thus, rotation limiter

128

may pivot about point

162

between the two extreme positions illustrated in

FIGS. 10 and 11

. Rotation limiter

128

preferably has a pair of tabs

130

,

132

that cooperate with sensors

140

and

142

, respectively, which are mounted in frame

144

. Sensors

140

,

142

are preferably micro switches but may be any type of sensor that is suitable for detecting the presence of tabs

130

,

132

. By respectively detecting the presence of tabs

130

and

132

, sensors

140

and

142

provide an indication of the direction in which patient support platform

20

has been rotated. A spring

136

is attached to rotation limiter

128

at over-center point

164

and to boss

134

at point

166

. Spring

136

keeps rotation limiter

128

in either of the two extreme positions until rotation limiter

128

is forced in the opposite direction by a stop pin

146

, as discussed below.

Still referring to

FIGS. 8

,

10

, and

11

, rotation limiter

128

has fillets

128

c

,

128

d

and flats

128

e

,

128

f

for engaging stop pin

146

, which is rigidly attached to crossbar

168

. When patient support platform

20

is in its initial supine position (i.e., the position corresponding to zero degrees of rotation and referred to herein as the “neutral supine position”), stop pin

146

is located at the top of its circuit between flats

128

e

and

128

f

. As used herein to describe the rotation of end ring

24

and, necessarily, patient support platform

20

, “positive” rotation means rotation in the direction of arrow

170

as shown in

FIG. 8

, and “negative” rotation means rotation in the direction of arrow

172

. As end ring

24

is rotated in the positive direction, stop pin

146

engages flat

128

f

and forces rotation limiter

128

into the extreme position shown in

FIG. 11

under the action of spring

136

. End ring

24

may be rotated slightly more than 360 degrees in the positive direction until stop pin

146

engages fillet

128

c

, at which point rotation limiter

128

prevents further positive rotation. End ring

24

may then be rotated in the negative direction to return to the neutral supine position. As end ring

24

approaches the neutral supine position, stop pin

146

will engage flat

128

e

. Further rotation in the negative direction beyond the neutral supine position will force rotation limiter

128

into the extreme position shown in

FIG. 10

under the action of spring

136

. End ring

24

may be rotated slightly more than 360 degrees in the negative direction until stop pin

146

engages fillet

128

d

, at which point rotation limiter

128

prevents further negative rotation. In this manner, stop pin

146

and rotation limiter

128

cooperate to limit the rotation of platform

20

so that the electrical wires in cable carrier

148

will not be ripped out of their mountings and the direct electrical connection will be preserved. Limiting rotation also serves to prevent tangling or extubation of patient care lines.

Referring to

FIGS. 8

,

9

,

12

, and

13

, the foot of bed

10

preferably has a positioning ring

122

with a central opening

118

through which patient care lines may pass as discussed above. Positioning ring

122

, which is preferably fastened to support bars

192

, has one or more circumferential holes

124

for cooperation with one or more longitudinal lock pins

120

to lock patient support platform

20

into one or more predetermined rotational positions. Preferably, the one or more lock pins

120

can only lock the patient support platform

20

into the zero degree supine position, so that the step of removing the lock pin will not impede quick rotation of the patient support platform

20

to the zero degrees supine position in the event that emergency care, such as cardiopulmonary resuscitation, is needed by the patient.

Lock pin

120

, which is mounted in upright frame

144

, is capable of limited longitudinal movement along its central axis to engage or disengage a hole

124

of positioning ring

122

, as desired. Preferably, lock pin

120

and positioning ring

122

include a twistable locking mechanism for preventing accidental disengagement of lock pin

120

from positioning ring

122

. For example, lock pin

120

may be provided with a protrusion such as nub

120

a

that fits through slot

124

a

of hole

124

. After pin

120

is pushed through hole

124

sufficiently for nub

120

a

to clear positioning ring

122

, handle

120

b

may be used to twist lock pin

120

such that nub

120

a

prevents retraction of pin

120

. Alternatively, lock pin

120

and positioning ring

122

may be respectively provided with cooperating parts of a conventional quarter-turn fastener or the like. Any such suitable device for preventing disengagement of lock pin

120

from positioning ring

122

by twisting lock pin

120

about its central axis is referred to herein as a twist lock.

FIG. 21

illustrates a lock pin

274

with a spring-loaded detent

278

and proximity switches

288

,

290

may be mounted to frame

144

with a bracket

272

. Lock pin

274

has a central boss

292

with a peripheral groove

280

for cooperation with ball

282

of detent

278

in the neutral position shown in FIG.

21

. In the neutral position, pin

274

is disengaged from hole

124

of locking ring

122

, and proximity switches

288

,

290

preferably send “neutral” signals to the control system to electrically prevent rotation of patient support platform

20

. If handle

276

is used to push pin

274

into engagement with a hole

124

of locking ring

122

, ball

282

of detent

278

engages edge

284

of boss

292

, and proximity switch

288

senses edge

286

of boss

292

and sends a “locked” signal to the control system to electrically prevent rotation of patient support platform

20

in addition to the mechanical locking of pin

274

in locking ring

122

. If motor-operated rotation of patient support platform

20

is desired, handle

276

may be used to pull pin

274

to its fully retracted position in which ball

282

of detent

278

engages edge

286

of boss

292

, and proximity switch

290

senses edge

264

of boss

292

and sends an “unlocked” signal to the control system to allow automated rotation of patient support platform

20

.

FIGS. 22 and 22A

illustrate an alternative three-position lock pin mechanism

298

comprising a lock pin

300

mounted on pin mounts

312

and

314

of yoke

310

. A block

308

is rigidly mounted on the lock pin

300

and slides between the pin mounts

312

and

314

. A push/pull knob

302

mounted on a back end

300

a

of the lock pin

300

is used to push or retract the lock pin

300

into one of three positions. In a “locked” position, the forward end

300

b

of the lock pin

300

is engaged into a hole

124

(

FIG. 9

) of locking ring

122

, mechanically preventing rotation of patient support platform

20

(FIG.

1

). In an “unlocked” position, the lock pin

300

is fully retracted so that edge

305

of block

308

abuts against pin mount

312

. Any position between these the “locked” and “unlocked” positions is defined as a “neutral” position.

Position detection switches

307

and

309

are toggled from their default states (open or closed) into their non-default states (closed or open) by the edge

305

of block

308

when the push/pull knob

302

is fully retracted. Likewise, position detection switch

313

is toggled into its non-default state by block

308

when the push/pull knob

302

is fully inserted. When engaged by the block

308

, position detection switch

307

closes a circuit that provides power to an electromechanical brake

332

(

FIG. 23

) used to impede movement of shaft

324

of a motor

322

that powers lateral rotation to the patient support platform

20

. The other position detection switches

309

and

313

transmit logic signals to control the motor control logic

338

operating the same motor. The combined feedback from switches

309

and

313

indicate whether the lock pin

300

is in the locked, unlocked, or neutral position.

Mounting brackets

316

disposed on either side of pin mount

314

are provided for bolting the lock pin mechanism

298

to the upright frame

144

(FIG.

12

). Furthermore, a spring loaded ball-bearing detent

311

impedes vibration or accidental movement of the block

308

out of the fully “locked” and “unlocked” positions.

As discussed in international application number PCT/IE99/00049, bed

10

preferably has a drive system essentially comprising a belt drive between patient support platform

20

and an associated electric motor

152

at the foot end of base frame

16

. The drive system may be of the type described in Patent Specification No. WO97/22323, which is incorporated herein by reference. As illustrated in

FIG. 14

, bed

10

preferably includes a quick release mechanism

156

installed on foot frame

144

to provide a means to quickly disengage patient support platform

20

from the belt drive system. Quick release

156

may be conveniently made from a tool and jig lever available from WDS Standard Parts, Richardshaw Road, Grangefield Industry Estate, Pudsey, Leeds, England LS286LE. Quick release

156

comprises a mounting tube

210

secured to foot frame

144

. A lever

222

is pinned to tube

210

at point

220

. A tab

218

extends from lever

222

, and a linkage

214

is pinned to tab

218

at point

216

. Linkage

214

is also pinned at point

212

to a shaft

208

that is slidably disposed within tube

210

. Shaft

208

extends through foot frame

144

toward belt

204

which is engaged with pulley

202

of the drive system. A roller

206

is attached to shaft

208

for engaging belt

204

. By rotating lever

222

in the direction of arrow

224

, roller

206

is forced into engagement with belt

204

, which provides sufficient tension in belt

204

to engage patient support platform

20

with the drive system. By rotating lever

222

in the direction of arrow

226

, roller

206

is retracted from belt

204

, which disengages patient support platform

20

from the drive system thereby allowing manual rotation of patient support platform

20

. This capability of quick disengagement of the drive system to allow manual rotation of patient support platform

20

is very useful in emergency situations, such as when a patient occupying bed

10

suddenly needs CPR. In such a circumstance, if patient support platform

20

is not in a supine position, a caregiver may quickly and easily disengage the drive system using quick release

156

, manually rotate patient support platform

20

to a supine position, lock the support platform

20

in place, and begin administering CPR or other emergency medical care.

As disclosed in international application number PCT/IE99/00049, the rotational position of patient support platform

20

, which is governed by motor

152

of the aforementioned drive system, may be controlled through the use of a rotary opto encoder. Alternatively, the rotational position of patient support platform

20

may be controlled through the use of an angle sensor

232

(shown schematically in

FIG. 13

) of the type disclosed in U.S. Pat. No. 5,611,096, which is incorporated herein by reference. As disclosed in the '096 patent, angle sensor

232

comprises a first inclinometer (not shown) that is sensitive to its position with respect to the direction of gravity. By mounting angle sensor

232

to patient support platform

20

in the proper orientation, the output signal from angle sensor

232

may be calibrated to control the rotational position of patient support platform

20

in cooperation with motor

152

. Likewise, angle sensor

232

may include another properly oriented inclinometer (not shown) that may be used in association with rams

15

and

17

(see

FIG. 1

) to control the Trendelenburg position of patient support platform

20

.

FIG. 23

illustrates an embodiment of a drive system

320

to control the rotational movement of the patient support platform

20

of therapeutic bed

10

. The drive system

320

comprises a stepper motor

322

operated by a stepper motor drive

338

controlled by control circuitry

335

which is in turn commanded by a computer

337

. The motor

322

further comprises a shaft

324

with a forward end

326

and a back end

328

opposite the forward end protruding from the motor

322

. A pulley

330

mounted on the forward end

326

of the shaft

324

receives a belt

204

(

FIG. 14

) to control the rotational movement of patient support platform

20

. A fail-safe electromechanical brake

332

is provided to engage shaft

324

and impede its rotation. The brake

332

is disengaged by supplying power to it, thereby allowing the shaft

324

to rotate freely under the control of motor

322

. This configuration prevents the shaft

324

, and by extension, the patient support platform

20

, from freely spinning if there is an interruption of power to the motor

322

and the brake

332

.

Preferably, the drive system

320

is integrated with the lock pin mechanism

298

(FIG.

22

). The position detection switch

307

regulates the flow of power from a power supply

334

to the clutch

332

. The switch

307

is closed when the lock pin

300

(

FIG. 22

) is fully retracted. When closed, power flows from the power supply

334

to the clutch

332

, allowing the shaft

324

to rotate freely or under the power of motor

322

. If the lock pin

300

is pushed into a “neutral” or “locked” position, the switch

336

reverts to the open position, engaging the clutch

332

to impede shaft

324

rotation.

The computer

337

, which ultimately controls the operation of stepper motor

322

, also receives signals from the locking pin mechanism

298

, namely, from position detection switches

309

and

313

, to detect the position of the lock pin

300

. The computer

337

may also receive signals from a CPR switch

339

. The CPR switch

339

is provided to interrupt any kinetic therapy program that may be running and cause the motor

322

to rotate the patient support platform

20

back to a supine position.

If the lock pin

300

is in the “locked” position, the computer

337

will cause the stepper motor

322

to halt rotation. This is in addition to the redundant stopping protection provided by the brake

332

. Likewise, if the lock pin

300

is in the “neutral” position, the computer

337

will normally stop the motor

322

from rotating, unless a “CPR” signal

334

is received, in which case the motor

322

will rotate the patient support platform

20

back to a supine position.

FIG. 24

is a block diagram illustrating another embodiment of a redundant hardware and software configuration

392

for operating the motors of therapeutic bed

10

of

FIG. 1. A

software-based computer

340

is provided to enable a user to monitor and control the operations of the therapeutic bed. The computer

390

relays signals to and from a motor controller circuit

342

through a parallel cable

390

to control the operation of the bed

10

. The computer also relays serial signals through a serial bus

391

that is shared by the computer

340

, a bed interface circuit

341

, and a surface interface circuit. The motor controller

342

operates the bed's stepper motor

344

, which rotates the patient support platform

20

. The motor controller

342

also operates the bed's head and foot lifts

345

and

346

, which incline the bed into Trendelenburg or reverse Trendelenburg positions.

Before the motor controller

342

can activate the stepper motor

344

, head lift

345

, or foot lift

346

in conformity with the commands received from the computer

340

via the parallel cable

390

, the motor controller

342

must first receive an enable signal

378

from the bed interface circuit

341

. The bed interface circuit

341

, in turn, will only relay an enable signal

378

if it receives an expected sequence of serial signals from the computer

340

over the bus

391

. Furthermore, the bed interface circuit

341

is configured to provide an enable signal

378

only if the sequence of serial enable signals from the computer

340

is received at regular intervals, for example, once every second. This redundancy minimizes the chances that an operating system crash on the computer

340

will cause the motors

344

through

346

to rotate in an unintended fashion. While it is not unusual for an operating system crash to freeze the output bits on a parallel port, the chances of an operating system crash causing the computer

340

to repeatedly generate the expected serial sequence over the bus

391

is infinitesimally small. In addition, both the computer

340

and the bed interface circuit

341

monitor the signals received from the other. If the computer

340

or bed interface circuit

341

detects a malfunction in the other, it will trigger an alarm to notify medical personnel of the malfunction.

It will be apparent to those of ordinary skill in the art, in light of the present specification, that other configurations could be devised to minimize the chances that the therapeutic bed

10

would rotate uncontrollably in the event of a system failure. For example, the motor controller

342

could be operated by the serial bus

391

rather than through the parallel cable

390

. Alternatively, the motor controller

342

itself could be configured to require a coded serial data stream at repeated intervals in order to activate any of the motors

344

through

346

. It will be understood that these alternative configurations fall within the scope of the present invention.

Further redundancy features are provided by monitoring devices

347

through

371

, which verify proper operation of the therapeutic bed

10

by monitoring the signals communicated from the motor controller

342

to motors

344

through

346

. The outputs of monitoring devices

347

through

371

are relayed to the bed interface circuit

341

, which encodes them to a serial data format for output onto the serial data bus

391

.

Also illustrated in

FIG. 24

are various inputs received by the surface interface circuit

343

, the bed interface circuit

341

, and the serial bus

391

, some or all of which information is encoded to a serial format so that it can be relayed to the computer

342

along the serial bus

391

. Bed interface circuit

341

receives inputs

376

from load cells provided to monitor the patient's weight and signals

377

from the lock pin mechanism

298

to indicate whether the bed is locked or unlocked. The surface interface circuit

343

receives input signals

373

from hoop sensors to detect whether there is a break in the end ring

22

(

FIG. 2

) and signals

374

from latch and buckle sensors and pressure sensitive tape switches

234

(

FIG. 17

) to indicate whether a patient is sufficiently secured for kinetic or prone therapy. The surface interface circuit

343

encodes the signals and relays them along the serial bus

391

through the cable carrier

148

back to the computer

340

. The serial bus

391

receives signals

375

from a Trendelenburg angle sensor indicating the angle at which the patient support platform

20

is inclined and from rotation angle sensors

232

(

FIG. 13

) indicating the angle of rotation of the patient support platform

20

.

FIG. 29

is a top view illustrating the use of honeycomb composite core panels to provide a lightweight yet strong radiolucent surface for the patient support platform

20

of FIG.

1

. First and second honeycomb composite core panels

682

and

686

with rectal hatches

684

are provided to support a patient. The first and second honeycomb composite core panels

682

and

686

are mounted on top of transverse beams (not shown) of a frame

680

of the patient support platform

20

.

FIGS. 30

a

and

30

b

illustrate one embodiment of the rollers

26

used to guide the upright end rings

22

and

24

of the therapeutic bed

20

. Two flanged ends

26

a

and

26

b

of the roller

26

prevent the end rings

22

and

24

from slipping off the roller

26

. The roller

26

is slidably and rotatably mounted on an axle

27

between two roller stops

27

a

and

27

b

. Preferably, one of the four or more rollers

26

used to guide the end rings

22

and

24

is fixed, that is, designed with minimal clearance

25

(such as less than 0.5 centimeters) between the flanges

26

a

and

26

b

and the respective roller stops

27

a

and

27

b

to stabilize the base frame

16

and end rings

22

and

24

on which the base frame

16

is mounted. Preferably, however, the other rollers are floating, that is, they are provided with greater clearance

25

(such as between approximately one and three centimeters) than was provided for the fixed roller. Making all but one of the rollers “float” permits the patients support platform

20

with its accompanying upright end rings

22

,

24

, to be manufactured and assembled with wider tolerances. This innovation solves a problem that may occur when, due to minor variations in the manufacture and construction of the patient support platform

20

, the end rings

22

and

24

would not otherwise be able to fit between the flanges

26

a

and

26

b

of all of the rollers

26

of the therapeutic bed

10

.

A preferred embodiment of the therapeutic bed

10

of the present invention constantly monitors a patient's weight.

FIG. 31

illustrates a weight monitoring system

430

comprising a plurality of caster mounted load cells

422

each providing a current or voltage output

423

proportional to the weight supported by each load cell

422

. The current or voltage output

423

of each load cell

422

is received by a corresponding analog-to-digital converter

434

and converted into a digital signal that is sent to a processor

436

(which may be a computer). The processor

436

sums the digital signals to determine the total load. The processor is communicatively coupled to a memory bank

438

, which stores the detected total weight

440

, the tare weight

442

of the bed (i.e., the total weight of the bed frame, cushions, sheets, and other bed and medical equipment attached to the bed, but not including the patient), and the patient's weight

444

. Preferably, the patient's weight

444

is recorded over time, providing a weight trend record for the patient.

Because the load cells

422

are mounted on the casters, a patient's weight can be measured regardless of the rotational or Trendelenberg angle of the patient support platform

20

.

An input/output interface

446

, such as a touch-screen monitor or a control unit having buttons, switches, and/or knobs, is communicatively coupled to the processor

436

. The input/output interface

446

provides several functions for operating the weight monitoring system

430

, including a zero function

448

, a hold function

452

, and a present patient weight function

450

.

Engaging the zero function

448

(by, for example, pressing a “zero button”) signals the processor

436

that the currently detected weight is the tare weight

442

of the bed. The processor

426

stores this load value in memory

438

as the tare weight

442

of the bed. Later, when a patient is placed on the bed, the processor

436

computes the patient's weight

444

by subtracting the tare weight

442

from the detected total weight

440

.

Selecting the hold function

452

(by, for example, pressing a “hold button”) signals the processor

436

to adjust the tare weight

442

to account for any weight added or subtracted during the hold period. The duration of the hold period may be preset, with the weight monitoring system

430

signaling the termination of the hold period with an indicator (such as a screen alert or audible beep). Alternatively, the hold function

452

may be toggled on and off, making the hold period last from the time the hold function

452

is toggled on until it is toggled off. While a hold is being applied, the weight monitoring system

430

may provide intermittent audible signals or a display reminding medical personnel to toggle the hold function

452

back off. The hold function permits medical personnel to add or remove bed accessories and medical equipment (such as pillows, IV bags, and intubation devices) to or from the bed without requiring the patient to be removed from the bed to recalibrate the tare weight

442

. Additionally, a preferred embodiment of the weight monitoring system

430

alerts medical personnel (for example, through an audible alarm) if significant or abrupt weight changes are detected when the hold function

452

is not activated or toggled on. This reminds medical personnel to activate the hold function

452

before adding or removing accessories or equipment from the bed.

The preset patient weight function

450

is provided to manually enter a patient's weight

444

into the weight monitoring system

430

. When this function is activated, the processor computes and records the tare weight

442

as the detected total weight

440

minus the value entered for the patient's weight

444

.

The weight monitoring system

430

also provides one or more weight display functions, preferably including a weight trend chart function

454

. The weight trend chart function

454

displays a group of statistics or graph representing the patient's weight trend over time. The weight trend chart function

454

helps medical personnel identify optimal and suboptimal courses of kinetic therapy. The weight trend chart function

454

also helps medical personnel detect excessive water retention or dehydration that may be caused by intubation-related treatments the patient is receiving.

The weight monitoring system

430

also comprises means for detecting and identifying malfunctioning load cells

422

. In the preferred embodiment, a multichannel analog-to-digital multiplexer

434

serially converts the output of each load cell

422

into a digital signal. The digital signals are then summed by the processor

436

to determine the total weight

440

borne by the load cells

422

. Because even an empty therapeutic bed

10

without any bed accessories or attached medical equipment will have some weight, each load cell

422

should signal at least a threshold amount of load. Accordingly, the processor

436

compares the digital signals received from the multiplexer

434

to preset digital thresholds corresponding to the minimum weight expected from each load cell

422

to detect anomolies that point to load cell failures. The processor may also compare the digital signals received from the analog-to-digital converters

434

to each other to detect unrealistic load disparities.

In light of the present disclosure, other means for detecting and identifying malfunctioning load cells will be readily apparent to those of ordinary skill in the art. For example, threshold comparisons could be done in analog rather than digital by using analog comparators to compare the output of each load cell

422

to present analog thresholds. Other analog comparators could compare the output of each load cell

422

to some multiple of the output of a nearby load cell

422

, to detect unrealistic disparities. It will be understood that these and other modifications fall within the scope of the present invention.

FIG. 32

is a flowchart illustrating an automated CPR function built into one embodiment of the therapeutic bed

10

of FIG.

1

. Preferably, one or more hardware-based CPR switches or buttons are mounted on the therapeutic bed

10

. Additionally, a software-based CPR button is provided on each screen of the touch-screen interface whose functions are illustrated in

FIGS. 35 through 44

. Preferably, the automated CPR function, whether activated through a switch or through a touch screen interface button, is achieved through a computer on the therapeutic bed

10

.

In block

580

, a person initiates the automated CPR function in a single step by, for example, pressing a CPR button. In block

581

, control circuity on the bed

10

discontinues any ongoing kinetic therapy regimen. Next, in block

583

a CPR screen is displayed on a touch screen interface. Preferably, the patient support platform

20

can only be locked in the 0 degrees supine position. However, if the platform

20

is locked at an angle not at the 0 degrees supine position, the CPR screen (not shown) alerts the operator to unlock the bed. Then, in block

584

, the base frame and patient support platform

20

are lowered to the lowest level position. Simultaneously in block

586

, the patient support platform is rotated to 0 degrees supine, so that the patient support platform

20

is parallel to the floor. Preferably, all of these movements take place in

40

seconds or less. In block

587

, the operator is alerted by a visual or audible signal to lock the bed. Once, as illustrated by function block

589

, the bed is locked, in block

590

an audible or visual announcement is provided confirming that the bed is locked.

FIG. 33

is a block diagram illustrating programmable therapy setting functionality incorporated into one embodiment of the therapeutic bed of the present invention. A logic unit

600

is provided to control the operation of one or more motors

602

to raise and lower the head and foot-ends of the patient support platform

20

. The logic unit

600

also controls the motor

604

that rotates the patient support platform

20

along the longitudinal axis of the therapeutic bed

10

. The logic unit

600

tracks the position of the patient support platform

20

with signals received from a direction indicator

606

, a longitudinal angle sensor

608

, and a lateral angle sensor

610

.

The logic unit

600

is communicatively coupled to a user interface

612

(see, e.g.,

FIGS. 35-43

) that enables an operator to select or program a course of kinetic therapy. The logic unit

600

is also communicatively coupled to memory

626

that stores a plurality of preprogrammed therapy settings

628

and statistics about past therapy in a therapy log

634

. The user interface

612

displays a description

614

of one or more preprogrammed therapy settings

628

, and allows an operator to scroll through other preprogrammed therapy settings

628

with buttons

616

and

620

. The user interface

612

also provides home

622

and help

624

buttons to display a home screen or a help screen.

The logic unit

600

is also communicatively coupled to a data import/export interface

636

, comprising, for example, a wireless modem

638

, some form of removable media

640

, such as a compact disc, floppy disc, or removable hard drive, or even a wired connection (not shown), such as a universal serial bus. The data import/export interface enables an operator to export the therapy settings

628

and therapy log

634

stored in memory

626

and to import new therapy settings

628

into memory

626

.

This aspect of the present invention satisfies the need for means to facilitate greater compliance by participants in research studies to a uniform kinetic therapy protocol. It also satisfies the need by doctors to develop and implement standardized kinetic therapy regimens to provide their patients.

FIG. 34

is a block diagram illustrating therapy logging functionality incorporated into one embodiment of the therapeutic bed of the present invention. A plurality of filters

660

are provided that receive signals from several status indicators

650

, including an angular sensor

652

, a direction indicator

654

, and a therapy setting indicator

656

. The filters

660

indicate when the patient support platform

20

is in the prone or supine position, when it is rotated at an angle of greater than 40 degrees from the prone or supine positions, and when a patient is undergoing kinetic therapy. The information provided by the filters

660

is transmitted to a memory storage unit

668

, which comprises a timer

670

, a recorder

672

, and memory

674

for recording total time spent in various types of stationary and kinetic therapy. The memory storage unit

668

is communicatively coupled to a display unit

676

. The display unit

676

displays a graphical representation of the kinetic therapy applied to the patient with respect to time. Alternatively, the display unit

676

displays raw kinetic therapy statistics as illustrated in FIG.

42

.

FIGS. 35 through 42

are graphical illustrations of several screens in one embodiment of a touch screen interface to monitor and control the various functions of the therapeutic bed

10

of the present invention.

FIG. 35

illustrates a home screen

700

which functions as a main menu for monitoring or operating the various functions of the therapeutic bed

10

. The home screen

700

displays several elements that are common to many other screens as well, including a screen caption

702

, a logo

704

, a help button

706

, and a CPR button

708

to initiate the automated CPR function of FIG.

30

. The home screen

700

further comprises a bed position graphic

710

which displays the current rotational position of the bed, a text area

714

which displays the angular rotational and Trendelenburg positions of the bed

10

, and a text area

712

which displays the current functional status of the bed (e.g., stopped, paused, parked, locked, and/or rotating).

The home screen

700

also displays several touch screen buttons

716

-

726

for monitoring or controlling the operation of the bed

10

. A prone/supine button

716

is provided to rotate the bed into the 0 degrees prone or 0 degrees supine position. (Preferably, whether “prone” or “supine” is displayed will depend on the rotational position of the patient support platform

20

. If in the supine position, the prone/supine button

716

will display “prone.” If in the prone position, the prone/supine button

716

will display “supine.”) A therapy settings button

718

is provided to program the angle limits and dwell times of a kinetic therapy regimen. A scale button

720

is provided to operate the weight monitoring system

430

(FIG.

31

). A bed position button

722

is provided to raise or lower the foot and/or head of the bed. A park button

724

is provided to rotate the patient support platform

20

to a stationary rotational position. A therapy meters button

726

is provided to view the amount of time a patient has been in kinetic therapy (see, e.g., FIG.

34

). The CPR button

708

mentioned earlier is provided to cause the patient support platform

10

to return to a supine and lowest possible flat position so that cardio-pulmonary resuscitation or other medical treatment can be applied to the patient (see FIG.

32

). Preferably, both the CPR button

708

and the help button

706

are provided on every screen of the touch screen interface.

Preferably, the home screen

700

also provides a hidden screen lockout button

810

(

FIG. 43

) to make the touch screen interface non-responsive to tactile input unless a code or password is provided or some other non-public procedure is followed to reactivate the touch screen. The hidden lockout button

810

may be provided behind the screen caption

702

, the logo

704

, or in some other predefined area of the home screen

700

. The hidden lockout button

810

may also be made provided in other screens. Providing a screen lockout function enables an operator to clean the touch screen interface without activating the bed, and also inhibits tampering by unauthorized persons (such as children) with the bed's functions.

FIG. 36

illustrates a prone checklist screen

728

of the touch screen interface of FIG.

35

. Like the home screen

700

, the prone checklist screen

728

displays the screen caption

702

, logo

704

, help button

706

, CPR button

708

, bed position graphic

710

, and text areas

712

and

714

. The prone checklist screen

728

also displays a group of procedure buttons

736

and a textbox

734

instructing the operator to perform several procedures to ensure that the patient is adequately secured by the patient support platform

20

. As the operator performs these operations, the prone checklist screen

728

displays a checkmark or some other indication next to each completed step. For those steps, if any, whose completion the therapeutic bed

10

is unable to automatically detect, the operator presses the displayed procedure button

736

to confirm that the associated procedure has been completed. A graphic

732

is optionally provided to illustrate each procedure that needs to be performed. Although not illustrated here, preferably a similar screen is provided to guide an operator through a checklist of procedures that must be performed prior to rotating a patient from prone to supine.

FIG. 37

illustrates a prone therapy settings screen

738

of the touch screen interface of FIG.

35

. Like the home screen

700

, the prone therapy settings screen

738

displays the screen caption

702

, logo

704

, help button

706

, and CPR button

708

. The prone therapy settings screen

738

also displays a back button

740

to return to the previous screen. Selectable text boxes and a set of increase and decrease buttons

752

are provided to set the left angle limit

742

, the right angle limit

744

, the left angle pause time

746

, the center pause time

748

, and the right angle pause time

750

. Although not illustrated here, preferably a similar screen is provided to display adjustable supine therapy settings as well.

FIG. 38

illustrates a scale functions screen

754

of the touch screen interface of FIG.

35

. Like the prone therapy settings screen

738

, the scale functions screen

754

displays the screen caption

702

, logo

704

, help button

706

, and CPR button

708

. The scale functions screen

754

also displays a home button

756

to return to the home screen

700

and a set-up wizard

755

to assist the operator in calibrating and operating the weight monitoring system

430

of the therapeutic bed

10

. A weight trends button

768

is provided to display weight trend data stored in memory

438

(FIG.

31

). A pair of increase and decrease buttons

752

are provided for inputting the patient weight

764

. By pressing a units button

758

, an operator can toggle between English and metric weight units. A save button

759

is provided to store the inputted patient weight

764

in memory

438

. Another pair of increase and decrease buttons

752

are provided to set a weigh delay time

766

to delay weighing the patient. A zero button

760

is provided to indicate that the current detected weight is the tare weight of the bed (i.e., that the current load does not include the patient). A hold button

762

is provided to suspend weighing until the hold button

762

is pressed again. Any bed accessories and medical equipment added or removed during the intervening time is attributed to the tare weight, rather than the patient weight.

FIG. 39

illustrates a weight trend screen

770

of the touch screen interface of FIG.

35

. Like the scale functions screen

754

, the weight trend screen

770

displays the screen caption

702

, logo

704

, help button

706

, CPR button

708

, and home button

756

. The weight trends screen

702

displays weight trend data in the form of a chart showing the patient weight

776

for a given date

772

and time

776

. A zero button

778

is provided to clear the chart. A save button

780

is provided to save the current patient weight to the weight trends chart.

FIG. 40

illustrates a bed height/tilt screen

782

of the touch screen interface of FIG.

35

. Like the scale functions screen

754

, the bed height/tilt screen

782

displays the screen caption

702

, logo

704

, help button

706

, CPR button

708

, and home button

756

. The bed height/tilt screen also displays graphics

786

and

788

illustrating the Trendelenburg tilt and overall height of the therapeutic bed

10

. A text area

784

displays the current Trendelenburg angle. Pairs of increase and decrease buttons

752

are provided to modify the Trendelenburg angle and overall elevation of the therapeutic bed.

FIG. 41

illustrates a supine park angle screen

790

of the touch screen interface of FIG.

35

. Like the scale functions screen

754

, the supine park angle screen

790

displays the screen caption

702

, logo

704

, help button

706

, CPR button

708

, and home button

756

. Selectable park angle buttons

792

,

794

,

796

,

798

, and

800

are provided to rotate the patient support platform

20

into one of several different standard park angles. An additional button or interface screen (not shown) may be provided to select a park angle other than 0 degrees, 45 degrees, or 60 degrees. Although not illustrated here, preferably a screen is provided that is similar to the supine park angle screen

790

to select a prone park angle.

FIG. 42

illustrates a therapy meters screen

802

of the touch screen interface of FIG.

35

. Like the scale functions screen

754

, the therapy meters screen

790

displays the screen caption

702

, logo

704

, help button

706

, CPR button

708

, and home button

756

. The therapy meters screen

802

displays the total time on the bed

804

and a table

806

displaying the total current day's and cumulative time spent in prone therapy, therapy greater than 40 degrees prone, supine therapy, and supine greater than 40 degrees prone.

FIG. 43

is a flow diagram of the touch screen interface of

FIGS. 35-42

showing the logical transition from the home screen

700

to other screens for controlling and monitoring the functions of the therapeutic bed

10

. Selecting the help button

706

on the home screen

700

or any of the other screens

728

,

738

,

754

,

770

,

782

,

790

or

802

activates a help utility

808

. Selecting the prone/supine button

716

prompts the display of a preparation screen

812

as the patient support platform

20

rotates to a position amenable for checking the tubing, head support, abdomen support, and arm slings before rotating to prone or supine. The screen logic then flows to the prone checklist screen

728

(

FIG. 36

) or a similar supine checklist screen (not shown). When the checklisted procedures are completed, screen logic flows next to a rotate screen

814

and then back to the home screen

700

.

Selecting the therapy settings button

718

invokes a therapy settings screen

816

having a prone settings selection button

818

and a supine settings selection button

820

. Selecting the prone settings button

818

invokes the prone therapy settings screen

738

(FIG.

37

). Selecting the supine settings button invokes a supine therapy settings screen

822

similar to the prone therapy settings screen

738

.

Selecting the scale button

720

invokes the scale functions screen

754

(FIG.

38

). Selecting the weight trend button

768

invokes the weight trend screen

770

(FIG.

39

). Selecting the bed position button

722

invokes the bed height/tilt screen

782

(FIG.

40

). Selecting the park button

724

invokes the supine park angle screen

790

(

FIG. 41

) if the bed is in a supine orientation, or a prone park angle screen (not shown) similar to the supine park angle screen

790

if the bed is in a prone orientation. Selecting the therapy meters button

726

invokes the therapy meters screen

802

(FIG.

42

). Selecting the screen lockout button

810

invokes a password dialog box or screen

824

for deactivating or reactivating the touch screen interface.

Selecting the CPR button

708

on any of screens

700

,

728

,

738

,

754

,

770

,

782

,

790

or

802

invokes a CPR mode screen

826

, which displays graphics and text areas illustrating the movement of the patient support platform

20

to the lowest flat supine position possible. The CPR mode screen

826

provides a cancel CPR button

828

, which, if selected, invokes a cancel CPR screen

830

indicating the termination of the automated CPR function.

FIG. 44

illustrates a data matrix

840

for use by technicians to diagnose the bed. The data matrix

840

summarizes current instrumentation readings and data stored in memory, including matrix data filenames, past therapy provided, current therapy settings, current bed status (e.g., locked, unlocked, angular position, lock pin status, instrumentation readings), and the patient's weight trend. The data matrix

840

shown in

FIG. 44

is illustrative and not exhaustive. Preferably, the touchscreen interface of

FIG. 35

is operable to display the data matrix

840

. Furthermore, the data matrix

840

may be exported through the data import/export interface

636

(

FIG. 33

) and sent to a technician who can diagnose the bed functions remotely.

FIGS. 35-44

are illustrative of some, but not all, of the screens or bed functions that may be provided for every embodiment of the therapeutic bed

10

. It would be a matter of ordinary skill in the art to adapt the present disclosure to provide additional screens and bed functions. It will be understood that all such adaptations, enhancements, and the like fall within the scope of the present invention.

The therapeutic bed

10

of the present invention is useful for rotating a patient from the supine to the prone position. Preferably, proning is provided in conjunction with regular oscillating therapy or frequent movements between different angular positions to intermittently relieve pressure on the dependent surfaces of the body. For example, rotating the patient support platform

20

from a first angular position to a second angular position at least 40 degrees from the first angular position at least every two hours may be adequate to minimize the risk of skin breakdown. To provide an additional pulmonary benefit, however, it is preferred that the patient support platform

20

be rotated back and forth across an arc of at least 80 degrees while in the prone position.

Using the therapeutic bed

10

of the present invention, rotational therapy may be paused for predetermined intervals of time when the patient support platform

20

reaches the right or left angle limits, or when the platform

20

reaches the zero degree prone position. In this manner, time spent in angles greater than 40 degrees can be increased, facilitating more secretion drainage from the lungs. For example, the patient support platform

20

can be operated to periodically pause during rotation at two to three discrete angular positions, where each of said two to three discrete angular positions is at least 40 degrees from the other of said two to three discrete angular positions, and where each pause is for a period of between fifteen seconds and ten minutes. Furthermore, rotation between one of said discrete angular positions to another of said two to three angular positions might occur at least every fifteen minutes, in order to periodically alleviate pressure from the weight-bearing surfaces of the body. This will mimic the repositioning behavior of healthy sleeping adults, which studies have shown reposition themselves about once every 11.6 minutes.

In operation, lateral rotational therapy in the prone position is preferably provided by rotating the patient support platform

20

no faster than 2 degrees per second in order to minimize stimulation of the vestibular system. Some patients may tolerate faster speeds. Slower speeds, such as 1 degree per second or less, may be indicated for patients suffering severe vestibular abnormalities. Accordingly, the therapeutic bed of the present invention provides an acclimate function that permits an operator to fully adjust the rotational speed of the patient support platform

20

.

Prone therapy is preferably provided in conjunction with kinetic therapy using an arc of rotation of at least 80 degrees. For example, the patient support platform

20

may be rotated from the prone position to a vertical (90 degree) position, back to the opposite (−90 degree) vertical position, and so forth. Alternatively, the patient support platform

20

may be rotated from the prone position all the way to the supine position, and then the rotation is reversed for 360 degrees until the platform

20

again reaches the supine position, and so forth. For patients with acute lung injury or ARDS, kinetic therapy in the prone position is preferably provided at least about 18 out of every 24 hours.

Angle limit modifications should be made for persons with injuries or fractures on one side of the body. For example, if one of patient's two lungs is more compromised than the other, rotation should be programmed to favor drainage away from the compromised lung. If the left lung is the more compromised lung, rotation should favor the right in order to place the “right lung” down. Preferably, the patient support platform

20

is paused at the right angle limit to maintain optimal oxygenation. Such therapy should be continued until the unilateral problem begins to resolve itself, at which point the patient support platform

20

can begin to be turned to the left side. Thereafter, the patient can be gradually acclimated to bilateral rotation by gradually increasing the left angle limits and left angle pause time every 2-4 hours until they match those given on the right. Also, patients with vestibular dysfunctions may be acclimated to kinetic therapy by gradually increasing the arc of oscillation from 0 degrees to preset angle of oscillation.

Also, kinetic therapy may be provided in conjunction with both the prone and supine positions. For example, a patient may be provided kinetic therapy in the supine position for a first interval of time (preferably for 1-6 hours), followed by prone therapy in the prone position for a second interval of time (again, preferably from 1-6 hours), and then returned to the supine position for further kinetic therapy. Such kinetic therapy may be punctuated by periods of static rest in the supine or prone positions.

A number of criteria may indicate that a course of kinetic therapy has accomplished its mission and may be discontinued. If the patient's perfusion to ventilation ratio rises above 250 for 24 hours and shows an upward trend, if the patient is extubated due to improvement, or if the patient becomes mobile or can sit up in a chair more three times a day for at least an hour each time, kinetic therapy may be discontinued.

Although the foregoing specific details describe a preferred embodiment of this invention, persons reasonably skilled in the art will recognize that various changes may be made in the details of the method and apparatus of this invention without departing from the spirit and scope of the invention as defined in the appended claims. Therefore, it should be understood that this invention is not to be limited to the specific details shown and described herein.

Number	Name	Date	Kind
3434165	Keane	Mar 1969	A
3827089	Grow	Aug 1974	A
4751754	Bailey	Jun 1988	A
4827541	Vollman	May 1989	A
4868937	Connolly	Sep 1989	A
4953243	Birkmann	Sep 1990	A
5224226	Groenewald	Jul 1993	A
5244231	Bauer	Sep 1993	A
5335313	Douglas	Aug 1994	A
5497518	Iura	Mar 1996	A
5611096	Bartlett	Mar 1997	A
5627512	Bogar	May 1997	A
5664270	Bell et al.	Sep 1997	A
5666104	Pollack	Sep 1997	A
5778887	Curtiss	Jul 1998	A
5831221	Geringer	Nov 1998	A
5864291	Walton	Jan 1999	A
5867639	Tuilier et al.	Feb 1999	A
6282736	Hand et al.	Sep 2001	B1

Number	Date	Country
WO 9627356	Sep 1996	WO
WO 9722323	Jun 1997	WO
WO 0007320	Feb 1999	WO
WO 9962454	Dec 1999	WO
WO 0000152	Jan 2000	WO
WO 0062731	Oct 2000	WO

	Number	Date	Country
Parent	09/821552	Mar 2001	US
Child	09/884749		US

Prone positioning therapeutic bed

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

RELATED APPLICATION INFORMATION

US Referenced Citations (19)

Foreign Referenced Citations (6)

Non-Patent Literature Citations (6)

Continuation in Parts (1)

Entry
J. Mahlke, Continuous Axial Rotation in prone Position—Clincial Experiences with a new Kinetic Device for Patients with Respiratory Distress, Abstract, date and other bibliographic information unknown.
R.J. Stiletto MD, Computer-Supported Continuous Axial Rotation Therapy in Prone Position for complex PolyTrauma Patients with ARDS, date and other bibliographic unknown.
R.J. Stiletto, The Role of Kinetic Therapy in the Treatment of Posttraumatic Respiratory Failure, http://www.med.uni-marburg.de/unfchir/forschung/f_lungentr_2.html, date and other bibliographic information unknown.
Barbara S. Marion, BSN, A Turn for the Better: ‘Prone Positioning’ of Patients with ARDS, American Journal of Nursing, v. 101 n.5, May 26, 2001, p. 26.
“Energy Chain Systems”, IGUS Catalog, pp. 1.36-1.39; May 2000.
R. Stiletto, Kinetische Therapie zur Therapie und Prophylaxe der posttraumatischen Lungeninsuffizienz, Der Unfallchirung 12-2000, pp. 1057-1064. Relevance: Discusses Kinetic Therapy.