The subject matter described herein relates to occupant supports, such as hospital beds, and to a method of responding to an acoustic signature, such as an alarm or alert, issued by a stand alone device.
Hospital beds and similar occupant or patient supports are often used in conjunction with items of medical equipment that are not components of the bed itself. Examples if these devices include occupant condition monitoring devices such as heart monitors, respiration monitors, pulse oximeters, and thermometers, as well as therapeutic devices such as respirators and sequential compression devices (SCD's) that apply periodically varying compression to an occupant's lower extremities to prevent deep vein thrombosis.
The occupant condition monitoring devices are designed to issue an audible alarm if the parameter detected by the device is “out of bounds”, for example if the occupant's heart rate exceeds an upper limit or if the oxygen saturation of the occupant's blood falls below a lower limit. The condition monitoring and therapeutic devices may also be designed to issue an audible alarm in the event of certain equipment malfunctions, for example if a respirator hose becomes disconnected or a heart monitor becomes disconnected from an electrical outlet. In addition a therapeutic device may be designed to issue an audible alert, which is less intense form of an alarm, when the device completes a commanded therapy session. For example an SCD device may be user programmable to operate for a prescribed period of time or a prescribed number of compression cycles after which it issues an alert to advise the attending caregiver staff that the therapy has been completed. The device may cease operation automatically upon completion of the prescribed therapy or could be designed to continue operating until a caregiver intervenes.
The audible alarm emitted by the monitoring or therapeutic device could be continuous or could be interrupted by periods of silence, similar to Morse code. Either way the alarm has a distinctive acoustic output related to its amplitude and frequency content and/or due to the sound/silence pattern of an interrupted signal. The device in question may offer the caregiver a selection of different alarm acoustic outputs so that he or she can distinguish among alarms issued by different types of equipment (e.g. a respirator as opposed to a heart monitor) or distinguish among different alarms issued by the same device (e.g. between an elevated heart rate and a depressed heart rate) or distinguish among different pieces of substantially identical equipment (e.g. between two different SCD pumps each serving a different occupant of a different bed in the same room). The devices may also offer the caregiver a selection of alarm volumes either as an intrinsic element of the selected alarm acoustic output or as an independently specifiable attribute of the selected alarm.
One shortcoming of the device alarms arises from the fact that the devices are not connected to a facility communication network such as a nurse call system. A member of the caregiver staff is unlikely to be in the immediate vicinity of the equipment and the affected patient at the moment the equipment alarm sounds. Instead the members of the staff are more likely to be occupied with other patients at other locations or on duty at a remote nurse's station. As a result the members of the caregiver staff may not be within earshot of the equipment issuing the alarm. Moreover, because the equipment is not a component of the bed, the alarm cannot cause the bed to undergo any change of state or configuration that might be beneficial for taking whatever action might be necessary to respond to the alarm. Instead, there will be an additional lapse of time after the caregiver arrives at bedside while the caregiver assesses the nature of the alarm and, if appropriate, adjusts the bed to a more desirable configuration.
A method for responding to an acoustic output issued by a stand alone device used in conjunction with an occupant support comprises receiving an acoustic signature corresponding to the acoustic output of the stand-alone device, determining if the received acoustic signature compares satisfactorily to a reference signature and, if the acoustic signature compares satisfactorily to a reference signature, issuing a notification to the occupant support, to an off-support destination or to both.
A related method for responding to an acoustic output issued by a stand alone device and caused by a defined condition comprises receiving an acoustic signature corresponding to the acoustic output of the stand-alone device and causing the occupant support to undergo a change of state from an initial state causally unrelated to the defined condition to a changed state.
A related apparatus is an occupant support suite comprising a bed, an acoustic sensor associated with the bed for receiving an acoustic signature emitted by a stand alone device, and a processor for a) comparing the received signature to a library of one or more reference signatures, and b) in the event the received signature compares satisfactorily to one of the reference signatures, issuing a notification to the bed, or to an off-bed destination, or to both.
The foregoing and other features of the various embodiments of the occupant support suite and related methods of responding to an acoustic output of a stand alone device described herein will become more apparent from the following detailed description and the accompanying drawings in which:
Referring to
Framework 32 also includes a segmented deck 60 comprised of a head or upper body deck segment 62, a seat deck segment 64, a thigh deck segment 66 and a calf deck segment 68 all supported on the elevatable frame. Linear actuators 80, 82 connect the elevatable frame and selected deck segments for operating the segments, specifically for adjusting the angular orientations β, θ, and δ of the upper body, thigh and calf segments.
Bed 20 also includes a mattress such as air mattress 90, a pair of turn bladders 92, 94, and a pump 100 which serves as an actuator for operating the mattress and turn bladders. Hose 102 connects pump 100 to mattress 90 so that the mattress can be inflated and pressurized by air provided by the pump. The mattress can be inflated to a pressure suitable for sustained support of an occupant (the sustained use pressure) or can be inflated to a higher prescribed pressure which provides a stiffer support useful for cardiopulmonary resuscitation. The pump can also deliver a sequence of pressure pulses to mattress 20 to provide percussion and vibration (P&V) therapy to a bed occupant. Hoses 104, 106 connect pump 100 to the turn bladders so that the bladders can be selectively inflated and pressurized.
The bed also includes an acoustic sensor 110, a processor 112, and a bed controller or control circuitry 114. The processor includes a library 116 (
Acoustic sensor 110 and processor 112 are associated with the bed by virtue of being mounted thereon.
Processor 112 is in communication with acoustic sensor 110 and with controller 114 by way of communication paths 120, 122. The controller also communicates with, among other things, actuator motor 44, linear actuators 80, 82, pump 100, and a facility communication network 118, such as a hospital nurse call system, by way of communication paths 124, 126, 132, 134, 138. The illustration suggests wired communication paths however other communication techniques such as optical and non-optical wireless techniques are also applicable.
Examples of stand alone devices include heart monitors, respiration monitors, oximeters, and body temperature monitors, all of which monitor physiological parameters of a bed occupant. Other examples include equipment respirators and SCD pumps, both of which apply therapy to a bed occupant. The devices are configured to emit an audible acoustic output 156 in response to a defined condition. For example if the device is a heart monitor it may be designed to emit an audible alarm output if the monitor perceives that the heart rate of the patient being monitored is not within defined upper and lower limits or if the patient's heartbeat is consistent with an abnormality such as ventricular tachycardia. A second example is a respirator designed to emit an alarm if an air tube extending from the respirator to the patient becomes disconnected. As already noted the audible output could be continuous or could be interrupted by periods of silence, similar to Morse code. Either way the emitted acoustic signal has a distinctive acoustic output related to its amplitude and frequency content and/or due to the sound/silence pattern of an interrupted signal. The device in question may offer the caregiver a selection of acoustically different alarms so that he or she can distinguish among alarms issued by different types of devices (e.g. a respirator as opposed to a heart monitor) or distinguish among different alarms issued by the same device (e.g. between an elevated heart rate and a depressed heart rate) or distinguish among two or more substantially identical devices (e.g. two different SCD pumps each serving a different occupant of a different bed in the same room). The devices may also offer the caregiver a selection of volumes either as an intrinsic element of the selected alarm or as an independently specifiable attribute of the selected alarm.
In practice a user engages the processor's learning mode and exposes the processor to a one or more alarm signatures corresponding to the alarm outputs of the stand alone devices expected to be used in conjunction with the bed. By doing so the user “teaches” the processor a family of signatures associated with the alarms. The teaching process enables the processor to associate each signature to which it is exposed with, for example, particular type of device, different types of alarms generated by a particular device, or different alarms generated by two or more examples of a particular device depending on the degree of specificity the user introduces into the teaching process. Alternatively or additionally the processor may include a pre-installed library of predefined alarm acoustic signatures to which it is expected to be exposed.
Referring additionally to
At blocks 204 and 206 comparitor 168 compares the received acoustic signature to each member of library 116 of acoustic signatures and determines whether or not the received, conditioned signal compares satisfactorily to a member of the library. In particular the processor tests whether or not V2(F) compares satisfactorily to one of the reference signatures (i.e. whether or not it matches one of the reference signals within some tolerance). As used herein, comparing an acoustic signature to a reference acoustic signature is the same as comparing equivalent representations of the acoustic signature and the reference signature, such as the Fourier transforms of a voltage as in the above example.
If the processor determines that the test signature (e.g. V2(F) compares satisfactorily to one of the library signatures, the processor issues a notification 208 to an off-bed destination 210, to the bed (specifically to controller 114) or to both.
An example off-bed destination 210 for notification 208 is a facility communication network 118 such as a nurse call system or a pager to notify one or more caregivers who are not within earshot of the device alarm that the device has issued an alarm. The content of the message conveyed through the communication system can be as specific as the specificity used during the teaching process or the specificity of any predefined reference signatures installed in the library.
Certain abnormalities related to patient condition, including the patient's physiological condition may indicate that the state of the bed should be changed from its existing physical or operational state to a physical or operational state more compatible with the well-being of a patient occupying the bed or to a physical or operational state more compatible with attending to the condition that caused the alarm. For example, if the notification were issued in response to an acoustic signature that compared satisfactorily to the heartbeat signature of a patient suffering ventricular tachycardia, the notification would provoke the controller to command the appropriate bed actuators (e.g. 44, 80, 82, 100) to place the bed in its CPR (cardiopulmonary resuscitation) configuration. The CPR configuration is one in which all the deck segments are at a substantially horizontal orientation, the deck is at working height satisfactory for CPR and, if the bed is equipped with an air mattress, the mattress is inflated or pressurized to a prescribed pressure which exceeds a sustained use pressure so that the mattress stiffness exceeds its sustained use stiffness. In another example if the notification were issued in response to an acoustic signature that compared satisfactorily to the signature of a patient suffering low oxygen saturation, the notification would provoke the controller to command the appropriate bed actuators to rotate upper body deck segment 62 to a substantially zero degree orientation angle β relative, to the elevatable frame. Another example change of state is illuminating lights 52.
Certain abnormalities related to a condition of the stand alone device may also indicate that the state of the bed should be changed from its existing or initial physical or operational state, which is not or is not known to be causally related to the defined condition that triggered the alarm, to a physical or operational state more compatible with the well-being of a patient occupying the bed or to a physical or operational state more compatible with attending to the condition that caused the alarm. For example, if the notification were issued in response to an acoustic signature that compared favorably to the signature corresponding to a respirator hose having become disconnected, the notification would cause the controller to command the appropriate bed actuators (e.g. pump 100) to change the state of the bed by discontinuing any ongoing operation, for example CLRT or P&V therapy, that might have been underway at the time notification 208 was issued. In the case of a cyclic operation such as CLRT the discontinuance could be delayed until completion of the current cycle or until the bed attained a state compatible with the well-being of a patient occupying the bed or with facilitating caregiver intervention. Another example change of state is illuminating lights 52.
The following table provides a matrix of stand alone devices, abnormal conditions that might be associated with each device, and possible responses thought to be compatible with patient well-being and/or with facilitating caregiver intervention. The entries in each cell of the matrix are nonexhaustive.
In some circumstances the step of determining if the received acoustic signature compares satisfactorily to a reference signature may be unnecessary. One possible example is if it were desired to accommodate only a single acoustic signature. In that case the step of causing the occupant support to undergo a change of state could be carried out as a result of having detected an acoustic signal without first having to compare the signal to a reference signal and determine if the signals match each other within some tolerance.
Although this disclosure refers to specific embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the subject matter set forth in the accompanying claims.