Patent Description:
The present invention further relates to a patient monitoring system comprising such a patient monitor control unit.

The present invention further relates to computer-implemented method of controlling a patient monitor.

The present invention further relates to a computer program product for implementing such a method.

The continuously shrinking form factor of ultrasound devices means that such devices can now be deployed as sensors (also as a wearable sensor), e.g. patches, such as for the sake of (semi-)continuous patient monitoring a clinical setting such as hospital or another medical facility. As is well-known per se, ultrasound devices may be used to collect haemodynamic data through the use of Doppler ultrasound, such as blood flow including peak flow, velocity and vascular diameter from which patient parameters such as arterial perfusion, circulatory volume status, fluid responsiveness, haemodynamic stability and so on may be derived. It for example may be useful to monitor such haemodynamic parameters in haemodynamically unstable patients, e.g. patients recovering from surgery.

Typically, such monitoring results are displayed on a patient monitor, i.e. a display device displaying one or more of such parameters on its display screen, where the parameters may be displayed as traces that progress in time across a dedicated display area such that a caregiver can evaluate the haemodynamic stability of the patient by evaluating the displayed traces. In addition, the patient monitor typically comprises a control unit that evaluates the haemodynamic data in order to generate an alarm upon detecting an anomaly in the haemodynamic data, such that a caregiver can be alerted and provide any medical attention the patient may need.

This is for instance known from <CIT>, which discloses a method for continuous non-invasive hemodynamic state monitoring in a subject by acquiring continuous ultrasound data via an ultrasound transducer attached to the subject. Continuous arterial waveforms are estimated based upon the acquired ultrasound data and hemodynamic parameters are derived for each cardiac cycle from the arterial waveforms. A current hemodynamic state of the subject is defined by setting limits on one or more hemodynamic parameters based upon the variation of these parameters over an initial period of time, which are used to continuously monitor a hemodynamic state of the subject by comparing a current state for one or more hemodynamic parameters of the subject to previously determined limits for the one or more hemodynamic parameters, and either outputting a trigger signal or alarm to a hemodynamic state monitor in an event that a change is detected in the current state of the one or more hemodynamic parameters or converting the arterial parameters into a continuous estimate of the arterial blood pressure in an event that a change is not detected.

When deploying an ultrasound device onto the patient for such monitoring, the ultrasound device is typically configurable in order to find a patient's artery (or organ of interest) for monitoring and/or optimizing the signal to noise ratio of the ultrasound echo signals acquired with the ultrasound device. For example, the ultrasound device may comprise a plurality of ultrasound transducers that may be individually addressed in a configurable manner in order to electronically steer, i.e. vary the angle of, the ultrasound beam produced by the ultrasound device in order to locate the patient's artery in the field of view of the ultrasound device. This may involve manual positioning of the ultrasound device onto the patient followed by electronic configuration of the ultrasound device to obtain the optimal configuration of the ultrasound device in terms of the aforementioned signal to noise ratio of its acquired echo signals.

A problem that is associated with such wearable ultrasound devices is that patient movement may cause the alignment of the ultrasound device relative to the patient's artery (or organ of interest) to be monitored to be disturbed, causing a deterioration in the signal quality produced by the ultrasound device. This will show as a sudden change in the haemodynamic data (including the haemodynamic parameters derived therefrom) on the patient monitor and can trigger false alarms as the cause of the change in the haemodynamic data is unrelated to a medical emergency. This is of course rather undesirable from the perspective of the caregiver, as such false alarms can waste precious time of the caregiver by the caregiver needlessly attending to the patient.

Hence, there exists a need for smart control of the patient monitor such that the generation of such false alarms is at least reduced.

<CIT> describes a monitoring apparatus for monitoring vital sign information of a subject, in particular for haemodynamic monitoring of a subject. The monitoring apparatus comprises a wearable ultrasound transducer, a control unit and a processing unit. The control unit may be adapted to steer the field of view towards the volume of interest on the basis of the variable ultrasound signal. The processing unit may be adapted to determine first and second periodical signal components of the variable measurement signal, to determine the vital sign information based on the first periodical signal component and to determine a signal quality based on the second periodical signal component.

The present invention seeks to provide a patient monitor control unit comprising a processor arrangement adapted to control a patient monitor to display haemodynamic data that can cause the patient monitor to display accurate haemodynamic data in a non-disruptive manner.

The present invention further seeks to provide a patient monitoring system comprising such a patient monitor control unit.

The present invention further seeks to provide to computer-implemented method of controlling a patient monitor that causes the patient monitor to display haemodynamic data that can cause the patient monitor to display accurate haemodynamic data in a non-disruptive manner.

The present invention further seeks to provide a computer program product for implementing such a method.

According to an aspect, there is provided a patient monitor control unit comprising a processor arrangement adapted to receive a series of ultrasound measurements received from (acquired by) a sensor comprising at least one configurable ultrasound transducer; process said series of ultrasound measurements to obtain haemodynamic data of a patient coupled to the sensor; control a patient monitor to display the obtained haemodynamic data; evaluate the obtained haemodynamic data to detect a variance in said data; and generate a reconfiguration signal for the at least one configurable ultrasound transducer, wherein the timing of said generation is a function of said evaluation.

The present invention leverages the evaluation of the haemodynamic data derived from the obtained series of ultrasound measurements can be used to decide when the ultrasound sensor needs to be reconfigured or recalibrated to reduce the risk of the haemodynamic data displayed on the patient monitor causing the generation of unnecessary alarms, e.g. when periodically recalibrating the ultrasound sensor. Such recalibration may lead to a change in the signal to noise ratio of the ultrasound measurements, i.e. the acquired ultrasound echoes, which can cause a sudden change in the values of the haemodynamic data, which in turn can cause the generation of an alarm. Such periodic recalibrations should therefore be performed with minimal impact on the visualization of the haemodynamic data.

On the other hand, where a sudden change in the alignment of the ultrasound sensor relative to the artery (or the organ of interest) being monitored causes the haemodynamic data to become unreliable or even unavailable, an immediate recalibration or even repositioning of the ultrasound sensor may be required to restore the desired ultrasound signals. In an embodiment, the processor arrangement therefore is adapted to compare the variance against a defined threshold and to time the generation of the reconfiguration signal as a function of said comparison. In this manner, where the variance remains within physiologically acceptable ranges, i.e. ranges that define normal variances of the haemodynamic data during one or more cardiac cycles of the patient, there is no need for immediate reoptimization of the ultrasound sensor positioning, such that the periodic optimization of the ultrasound sensor can be performed at a point in time where such optimization does not affect the haemodynamic data displayed on the patient monitor.

For example, the patient monitor may have a dedicated display region onto which the haemodynamic data is displayed, the haemodynamic data of a single series of ultrasound measurements spanning the full width of said dedicated display region, and wherein the processor arrangement may be adapted to generate the reconfiguration signal in between successive series of ultrasound measurements if the detected variance is below the defined threshold. Consequently, as the reconfiguration of the ultrasound sensor is performed whilst the patient monitor reinitializes the displaying of the haemodynamic data in order to display the haemodynamic data derived from the next series of ultrasound measurements, no sudden changes in the haemodynamic data resulting from the reconfiguration of the wearable ultrasound sensor are displayed on the patient monitor.

The processor arrangement may be adapted to immediately generate the reconfiguration signal if the detected variance exceeds the defined threshold as in this scenario either the haemodynamic data has become unreliable or the patient needs medical attention, such that by repeating the measurement with a reconfigured sensor a distinction between these two options can be made.

In a further refinement, the processor arrangement is adapted to receive vital signs information of the patient from a further sensor; compare the detected variance against the received vital signs information; and immediately generate the reconfiguration signal in case of the detected variance deviating from the received vital signs information. In such a case the variance is most likely caused by a loss of alignment of the wearable ultrasound sensor relative to the artery being monitored, such that reconfiguration of the wearable ultrasound sensor is required to potentially restore this alignment.

The processor arrangement may be further adapted to change a visualization of the obtained haemodynamic data on the patient monitor in response to detecting said variance in order to warn an observer of the patient monitor that the displayed haemodynamic data may have become unreliable. This may be preferable over the generation of an audible alarm as such as alarm will attract a caregiver to address the needs of the patient, whereas upon reconfiguration of the wearable ultrasound sensor it may prove that such an alarm was false, e.g. where the variance was caused by a loss of alignment of the wearable ultrasound sensor.

The processor arrangement may be further adapted to receive a further series of ultrasound measurements received from the wearable sensor; process said further series of ultrasound measurements to obtain further haemodynamic data of the patient; compare the further haemodynamic data with the haemodynamic data; and generate an alarm if the further haemodynamic data differs from the haemodynamic data by less than a defined amount. In this case, the reconfiguration of the wearable ultrasound sensor did not significantly affect the haemodynamic data, such that it is most likely that in this case the change in the haemodynamic data is caused by a physiological change of the patient, who therefore may require medical attention.

Such an alarm may be an audible alarm generated by the patient monitor or alternatively may be a signal that generate the alarm on a remote electronic device such as a pager, smart phone or the like. To this end, the patient monitor control unit further comprises a communication module for communicating with an external device, and wherein the processor arrangement is further adapted to transmit the generated alarm to the external device with the communication module. In this manner, a caregiver in a remote location (outside audible range of the patient monitor) may still be alerted to the patient requiring medical attention.

According to another aspect, there is provided a patient monitoring system comprising the patient monitor control unit according to any of the herein described embodiments, a patient monitor under control of the patient monitor control unit and a sensor comprising at least one configurable ultrasound transducer communicatively coupled to the patient monitor control unit. Such a patient monitoring system may be used to continuously monitor the haemodynamic data of the patient whilst minimizing the generation of false alarms by the patient monitor as explained above.

In an embodiment, the processor arrangement further is adapted to configure the at least one configurable ultrasound transducer. To this end, the processor arrangement may be adapted to configure the at least one configurable ultrasound transducer by systematic adjustment at least one of the ultrasound beam angle produced by the sensor (wearable sensor), density of the ultrasound beams within a scanning plane (or a volume), frequency of the ultrasound beam, etc. in order to optimize the signal-to-noise ratio of the echo signals acquired with the wearable ultrasound sensor.

According to yet another aspect, there is provided a computer-implemented method of operating a patient monitor control unit, the method comprising receiving a series of ultrasound measurements received from a sensor comprising at least one configurable ultrasound transducer; processing said series of ultrasound measurements to obtain haemodynamic data of a patient coupled to (or wearing) the sensor (or wearable sensor); controlling a patient monitor to display the obtained haemodynamic data; evaluating the obtained haemodynamic data to detect a variance in said data; and generating a reconfiguration signal for the at least one configurable ultrasound transducer, wherein the timing of said generation is a function of said evaluation. As explained above, such a method ensures that reconfiguration of the sensor is performed whilst minimizing the disruption of the continuity of the haemodynamic data are displayed on the patient monitor by evaluation of this data and implementing a smart reconfiguration strategy that ensures that such disruption is minimized.

For example, in a scenario where the patient monitor has a dedicated display region onto which the haemodynamic data is displayed, the haemodynamic data of a single series of ultrasound measurements spanning the full width of said dedicated display region, the method further may comprise comparing the variance against a defined threshold; and generating the reconfiguration signal in between successive series of ultrasound measurements if the detected variance is below the defined threshold such that any change in the values of the haemodynamic data caused by such reconfiguration are not visualized on the patient monitor.

On the other hand, the method may further comprise immediately generating the reconfiguration signal if the detected variance exceeds the defined threshold as in this case the patient may need immediate medical attention as explained above.

According to still another aspect, there is provided a computer program product comprising a computer readable storage medium having computer readable program instructions embodied therewith for, when executed on the processor arrangement of the patient monitor control unit of any of the herein described embodiments, cause the processor arrangement to implement the method of any of the herein described embodiments. Such a computer program product may be used to configure existing patient monitoring systems to implement the embodiments of the present invention, thereby avoiding the need for such existing patient monitoring systems to be replaced. As such, the availability of such a computer program product is a cost-effective manner of implementing the embodiments of the present invention.

Embodiments of the invention are described in more detail and by way of non-limiting examples with reference to the accompanying drawings, wherein:.

<FIG> schematically depicts a patient monitoring system <NUM> according to an example embodiment of the present invention. The patient monitoring system <NUM> comprises a patient monitor <NUM> under control of a patient monitor control unit <NUM>. The patient monitor control unit <NUM> is adapted to receive ultrasound signals, e.g. ultrasound Doppler signals or image data, from an ultrasound sensor <NUM>, which is in case of the wearable embodiment is positioned on a body portion <NUM> such as an arm or a leg of a patient in order to monitor an artery <NUM> within the body portion <NUM>. More particularly, the wearable ultrasound sensor <NUM> typically is arranged to obtain a series of ultrasound measurements from which the patient monitor control unit <NUM> can derive haemodynamic data pertaining to the blood flow through the artery <NUM> of the patient and control the patient monitor <NUM> to display the derived haemodynamic data on the display screen of the patient monitor <NUM>. The ultrasound sensor <NUM> can be either a wearable ultrasound sensor or a transesophageal echocardiography (TEE) probe coupled to patient (placed into the patient's esophagus) and arranged to acquire ultrasound data representative of the internal structures of the heart and the heart's major vessel.

The patient monitor control unit <NUM> typically comprises a processor arrangement including one or more processors, here depicted by way of non-limiting example by a computing unit <NUM> that receives the ultrasound measurement data from the ultrasound sensor <NUM> and processes the received ultrasound measurement data to obtain the haemodynamic data to be displayed on the patient monitor <NUM> and optionally to perform evaluations of the obtained haemodynamic data such as to determine trends in the haemodynamic data over time such as a variance in the haemodynamic data across a series of ultrasound measurements received from the wearable ultrasound sensor <NUM>. In the context of the present application, where reference is made to a series of ultrasound measurements it should be understood that this refers to a plurality of measurements performed during one or more cardiac cycles of the patient from which the haemodynamic data pertaining to these cardiac cycles can be derived. The ultrasound measurements comprise at least one of: ultrasound Doppler measurements, measurements performed on ultrasound B mode or M mode data, from which such haemodynamic data can be derived. The processor arrangement as shown in <FIG> further comprises a synchronization unit <NUM> that synchronizes between the computing unit <NUM> and the patient monitor <NUM>, for example to avoid a reconfiguration of the ultrasound sensor <NUM> causing a disruption of the continuity of the haemodynamic data displayed on the patient monitor <NUM>. Although the computing unit <NUM> and the synchronization unit <NUM> are shown as separate entities, it will be immediately apparent to the skilled person that such units may be realized by a single processor or a plurality of processors working together, e.g. separate processors or discrete processor cores of a single multi-core processor.

The patient monitor control unit <NUM> may be responsive to the user interface <NUM>, which may take any suitable form. For example, the user interface <NUM> may be a touchscreen of the patient monitor <NUM> or of a separate device that is communicatively coupled to the patient monitor control unit <NUM> in a wired or wireless fashion. Alternatively, the user interface <NUM> may take the form of a touchpad, keyboard, mouse, trackball and so on or combinations thereof as will be immediately apparent to the skilled person. The user interface <NUM> may be used by a user of the patient monitoring system <NUM> to configure which haemodynamic data is to be displayed on the display screen of the patient monitor <NUM>. For example, the user may select one or more haemodynamic waveforms such as (beat-to-beat variability in) flow or peak flow, velocity and vascular diameter (PFV, PVV and VDV) and derived parameters such as arterial perfusion, circulatory volume status, fluid responsiveness and haemodynamic status to be displayed on the patient monitor <NUM>, potentially together with an ultrasound image of the patient's artery as captured by the wearable ultrasound sensor <NUM>.

The patient monitor control unit <NUM> may be responsive to a further patient monitoring device such as a ventilator, an ECG monitoring device and so on from which the patient monitor control unit <NUM> receives further vital signs information of the patient being monitored with the wearable ultrasound sensor <NUM>. As will be readily understood by the skilled person, the user of the patient monitoring system <NUM> may configure the system to also display such further vital signs information onto the patient monitor <NUM>, e.g. through the user interface <NUM>.

The patient monitor control unit <NUM> may further comprise an alarm generation unit <NUM> for generating an alarm when the computing unit <NUM> detects an anomaly in the haemodynamic data derived from the series of ultrasound measurements received from the wearable ultrasound sensor <NUM>. Such an alarm generation unit <NUM> may take any suitable form such as that of a loudspeaker or the like for generating an audible alarm, a communication module for transmitting the alarm to a remote device <NUM> such as a pager, smart phone or the like in order to alert a caregiver to the fact that such an anomaly has been detected. Such a communication module may be a wireless communication module implementing any suitable wireless communication standard such as Wi-Fi, Bluetooth, a mobile communication standard such as GSM or UMTS, and so on. Alternatively, the communication module may be a wired communication module that relays the alarm signal to a remote device <NUM> over a wired network using any suitable communication protocol. The alarm generation unit <NUM> in yet another embodiment is adapted to generate both an audible alarm as well as alarm signal for the remote device <NUM>.

The wearable ultrasound sensor <NUM> may comprise a plurality of ultrasound transducers such as piezoelectric transducers or preferably capacitive micro-machined ultrasound transducers (CMUTs), which may be individually addressable in order to configure the operation of the wearable ultrasound sensor <NUM>. For example, the individual addressing of the ultrasound transducers may be controlled to configure the beam angle of the ultrasound beam produced with the wearable ultrasound sensor <NUM> as indicated by the solid and dashed arrows emanating from the wearable ultrasound sensor <NUM> in <FIG>. Such configuration of the wearable ultrasound sensor <NUM> may be used to bring the artery <NUM> of the patient in the field of view of the wearable ultrasound sensor <NUM> after placement of the wearable ultrasound sensor <NUM> on the body region <NUM> of the patient. In another example, the reconfiguration signal provided to the configurable ultrasound transducer can be an instruction of varying a frequency of the ultrasound beam. In particular, this embodiment may be realized in an optimized way using the CMUT transducers, because their operational frequency can be varied in a larger frequency range (from about <NUM> to <NUM>) compared to the piezoelectric transducers. Scattering of the ultrasound beam by a tissue is revers proportional to the ultrasound beam's frequency, thus if a vessel moves deeper in the tissue, while the sensor is monitoring, a reduction of the frequency of the ultrasound beam would improve the beam's penetration into said tissue. In yet another example, the reconfiguration signal may be an instruction of varying a density of the ultrasound beams within a scanning plane (or a volume). The density and frequency of the ultrasound beam sonicating a region of interest defines a resolution of ultrasound data acquired from this region. However, an increased density, thereby resolution, might require a longer scanning time in order to obtain the ultrasound data of the given region of interest. Therefore, it might be desirable only, when specific evaluation criteria of the obtained haemodynamic data are met, to increase the density of the ultrasound beam. Configurations of the ultrasound transducer presented above help enabling improved signal to noise ratio of the ultrasound measurements (acquired data) thereby improving a quality of the derived therefrom haemodynamic data.

The wearable ultrasound sensor <NUM> may come in any suitable form, such as an adhesive patch, a sensor that is strapped to the body portion <NUM> or a combination thereof. Other suitable embodiments of the wearable ultrasound sensor <NUM> for securing the wearable ultrasound sensor <NUM> to the body region <NUM> of the patient will be immediately apparent to the skilled person. The wearable ultrasound sensor <NUM> may comprise a configuration unit (not shown) responsive to the synchronization unit <NUM> of the patient monitor control unit <NUM>, which configuration unit may be adapted to configure the wearable ultrasound sensor. Alternatively, the processor arrangement of the patient monitor control unit <NUM>, e.g. the computing unit <NUM> and/or the synchronization unit <NUM> may be adapted to configure the wearable ultrasound sensor <NUM> as will be explained in more detail below.

<FIG> schematically depicts an example configuration of the display screen of the patient monitor <NUM> on which a number of display regions <NUM>, <NUM>, <NUM> and <NUM> are shown. Such display regions may be used to display different types of relevant information, such as patient ID, wearable ultrasound sensor ID, continuous graphs of the monitored haemodynamic data or parameters derived therefrom as previously explained, trends in the monitored haemodynamic data or parameters derived therefrom and ultrasound images captured with the wearable ultrasound sensor <NUM>. Where a display region <NUM> is dedicated to the display of the monitored haemodynamic data, e.g. graphs or trends of such data or its derived parameters, the data is typically displayed as a trace that progresses from left to right across the display screen until the trace reaches the end point <NUM> of the display region <NUM>. At this point in time, the display region is refreshed and a new trace is shown beginning at the opposite end of the display region <NUM> as is well-known per se. The display region <NUM> may have a width W such that a trace spanning the width W of the display region <NUM> covers the haemodynamic data or parameters derived thereof of exactly one series of ultrasound measurements captured with the wearable ultrasound sensor <NUM>. Such a series may include any suitable number of cardiac cycles of the patient as previously explained. Typically, such a series will include a plurality of cardiac cycles.

One of the key insights of the present invention at least in some embodiments is that when the display screen of the patient monitor <NUM> is refreshed following the trace of the haemodynamic data or parameters derived thereof of a complete series of ultrasound measurements reaching the end point <NUM> of the dedicated display region <NUM> displaying this trace, a change in the magnitude of this data or derived parameters will be difficult to notice because the next data point, i.e. the first data point derived from the next series of ultrasound measurements, is shown at the opposite end of the dedicated display region <NUM>. Such a change in magnitude for example may be expected when the wearable ultrasound sensor <NUM> is reconfigured, e.g. its beam properties (angle, density, frequency, etc.) is readjusted, as this typically causes a change in the intensity of the Doppler signals obtained with the wearable ultrasound sensor <NUM>. Such periodic reconfiguration of the wearable ultrasound sensor <NUM> may be desirable in order to ensure that the haemodynamic data derived from the ultrasound measurements (acquired ultrasound data) performed with the wearable ultrasound sensor <NUM> remain reliable over a prolonged period of time, e.g. to counteract small changes in the alignment of the wearable ultrasound sensor <NUM> relative to the artery <NUM> of the patient.

Therefore, in at least some embodiments of the present invention, the processor arrangement of the patient monitor control unit <NUM> is adapted to generate a reconfiguration signal at the end of a complete series of ultrasound measurements, i.e. in between successive series of ultrasound measurements such that any associated change in the magnitude of the haemodynamic data or parameters derived therefrom is not apparent on the patient monitor <NUM> due to the fact that this change in magnitude does not appear within a trace displayed in the dedicated display region <NUM> of the patient monitor <NUM> but instead appears in between traces during the refreshing of the patient monitor <NUM>. Such periodic reconfiguration of the wearable ultrasound sensor <NUM> may occur at any suitable frequency, e.g. after each complete series of ultrasound measurements or after the completion of N series of ultrasound measurements in which N is a positive integer having a value of at least <NUM>.

This reconfiguration strategy may be deployed where the computing unit <NUM> considers that the haemodynamic data derived from the ultrasound measurements is stable enough to warrant the delay of the reconfiguration of the wearable ultrasound sensor <NUM> to the end of a trace displayed in the dedicated display region <NUM> of the patient monitor <NUM>, i.e. at the completion of a series of ultrasound measurements performed with the wearable ultrasound sensor <NUM>. However, if the computing unit <NUM> considers that the haemodynamic data derived from the ultrasound measurements is likely to have become unstable or unreliable, an immediate reconfiguration of the wearable ultrasound sensor <NUM> may be forced by the generation of a reconfiguration signal with the synchronization unit <NUM> and the provision of the signal to the wearable ultrasound sensor <NUM>. Such an immediate reconfiguration of the wearable ultrasound sensor <NUM> therefore may take place during a series of ultrasound measurements such that the trace displayed in the dedicated display region <NUM> of the patient monitor <NUM> may exhibit a sudden change in the magnitude of the displayed haemodynamic data or parameters derived thereof as caused by the reconfiguration of the wearable ultrasound sensor <NUM>. This will be explained in further detail with the aid of <FIG>, which depicts a flowchart of a method <NUM> implemented by the processor arrangement of the patient monitor control unit <NUM>.

The method <NUM> commences in operation <NUM> with the (manual) positioning of the wearable ultrasound sensor <NUM> on the body region <NUM> of the patient and the initial configuration of the wearable ultrasound sensor <NUM> in order to bring the artery <NUM> within the body region <NUM> of the patient into the field of view of the wearable ultrasound sensor <NUM>. This will be explained in further detail with the aid of <FIG> and <FIG>, which will be described below. Upon the initial configuration of the wearable ultrasound sensor <NUM> in this manner, the method <NUM> proceeds to operation <NUM> in which the patient monitor control unit <NUM> receives the ultrasound measurements (acquired ultrasound data) from the wearable ultrasound sensor <NUM> and processes those measurements as explained above in order to derive the haemodynamic data and associated parameters from the received ultrasound measurements, and displays the derived data and associated parameters of the patient monitor <NUM> in accordance with a user-specified configuration of the patient monitor <NUM> for instance as previously explained.

In operation <NUM>, the computing unit <NUM> of the patient monitor control unit <NUM> evaluates the haemodynamic data (or the parameters derived therefrom) to detect a beat-to-beat variance in the haemodynamic data derived from the ultrasound measurements. For example, the computing unit <NUM> may compare successive data points relating to the same phase of the cardiac cycle but belonging to different heartbeats in order to detect such a variance. The computing unit <NUM> then proceeds to operation <NUM> in which the variance between such data points (including a zero variance) is compared against a defined threshold. This threshold typically represents a physiologically relevant threshold. In other words, a variance below this threshold is unlikely to represent a physiologically relevant event, whereas a variance above this threshold is likely to represent a physiologically relevant event, that is, a physiological change in the patient being monitored, which may be indicative of the patient requiring urgent medical attention.

If the detected variance is below this defined threshold, the method proceeds to operation <NUM> in which it is checked if the trace displayed in the dedicated region <NUM> of the patient monitor <NUM> has reached the endpoint <NUM> of the dedicated region <NUM>. If this is the case, the method <NUM> proceeds to operation <NUM> in which the synchronization unit <NUM> generates the reconfiguration signal for the wearable ultrasound sensor <NUM> in order to reconfigure the wearable ultrasound sensor <NUM> whilst the patient monitor <NUM> is refreshing as previously explained, after which the method <NUM> proceeds to operation <NUM> in which it is checked if the monitoring of the patient is to be continued. If this is the case, the method <NUM> returns to previously described operation <NUM>, whereas if the monitoring of the patient is to be terminated the method <NUM> terminates in operation <NUM>. Similarly, if it is decided in operation <NUM> that the trace displayed in the dedicated region <NUM> of the patient monitor <NUM> has not yet reached the endpoint <NUM>, the method proceeds to the previously described operation <NUM> or alternatively returns directly to operation <NUM> (not shown).

If the evaluation of the detected variance in operation <NUM> determines that this variance is above the defined threshold, the method <NUM> proceeds to operation <NUM> in which the detected variance in the haemodynamic data derived from the ultrasound measurements provided by the wearable ultrasound sensor <NUM> is compared against vital signs data provided by the further device(s) <NUM>. If the vital signs data provided by the further device(s) <NUM> shows a similar variance, then the variance detected in the haemodynamic data is indicative of an actual physiological change in the patient such that the alarm generation unit <NUM> of the patient monitor control unit <NUM> may generate the aforementioned alarm to attract the attention of a caregiver such that the patient can receive the necessary medical attention. In this scenario, no immediate reconfiguration of the wearable ultrasound sensor <NUM> is required such that the method <NUM> proceeds to the previously described operation <NUM>.

Alternatively, the alarm generation unit <NUM> may be adapted to immediately generate the alarm upon detecting a variance in the haemodynamic data above the defined threshold, with the alarm being terminated if the comparison of the variance in the haemodynamic data with the vital signs data provided by the further device(s) <NUM> shows that the variance in the haemodynamic data is unexpected, i.e. is not replicated in the vital signs data as in such a scenario the variance is unlikely to be the result of an actual physiological change in the patient but instead is likely to be caused by a change in the alignment of the wearable ultrasound device <NUM> relative to the artery <NUM> of the patient.

In such a case, the method <NUM> may proceed to operation <NUM> in which the visualization of the haemodynamic data on the patient monitor is altered to indicate that the displayed haemodynamic data values (or parameter values) have become unreliable. This for example may be achieved by changing the color of the trace displayed in the dedicated display region <NUM> and/or by changing the color of a numerical value displayed on the patient monitor <NUM>. Additionally or alternatively, the computing unit <NUM> may calculate a reliability score for the haemodynamic data to be displayed on the patient monitor <NUM> and control the patient monitor <NUM> to display this reliability score such that a change, e.g. a reduction, of this score is indicative of the haemodynamic data potentially having become unreliable.

The method <NUM> subsequently proceeds to operation <NUM> in which a reconfiguration signal for the wearable ultrasound sensor <NUM> is immediately generated with the synchronization unit <NUM> in order to perform an electronic recalibration of the wearable ultrasound sensor <NUM> in order to realign the wearable ultrasound sensor <NUM> with the artery <NUM> of the patient. Upon performing this recalibration, a further series of ultrasound measurements is received from the wearable ultrasound sensor <NUM> from which further haemodynamic data is extracted and compared against the haemodynamic data obtained prior to the recalibration of the wearable ultrasound sensor <NUM>. If the further haemodynamic data is sufficiently different to the pre-recalibration haemodynamic data, i.e. the variance between a data point in the further haemodynamic data and a data point in the pre-recalibration haemodynamic data prior to the misalignment of the wearable ultrasound sensor <NUM> is below the defined threshold, the electronic recalibration of the wearable ultrasound sensor <NUM> has been successful such that the method <NUM> may proceed to the previously described operation <NUM>.

On the other hand, if the further haemodynamic data is substantially similar to the pre-recalibration haemodynamic data, i.e. the variance between a data point in the further haemodynamic data and a data point in the pre-recalibration haemodynamic data prior to the misalignment of the wearable ultrasound sensor <NUM> remains above the defined threshold, the electronic recalibration of the wearable ultrasound sensor <NUM> has been unsuccessful, in which case the method <NUM> proceeds to operation <NUM> in which the alarm generating unit <NUM> of the patient monitor control unit <NUM> generates an alarm for the caregiver to manually reposition the wearable ultrasound sensor <NUM> in operation <NUM>, after which the method <NUM> proceeds to operation <NUM> in which the electronic recalibration of the wearable ultrasound sensor <NUM> is performed as previously explained. It is noted for the avoidance of doubt that operation <NUM> is not performed by the processor arrangement of the patient monitor control unit <NUM> and as such does not form part of any of the computer-implemented methods that are claimed as part of the present application.

At this point, the positioning and calibration of the wearable ultrasound sensor <NUM> will be explained in further detail with the aid of <FIG>, which depicts a flowchart of a positioning and calibration method of the wearable ultrasound sensor <NUM>, here a <NUM>-D ultrasound sensor. The method commences in operation <NUM> with the provision of the wearable ultrasound sensor <NUM> after which the method proceeds to operation <NUM> in which the wearable ultrasound sensor <NUM> is manually positioned onto the body region of the patient by the caregiver and the wearable ultrasound sensor <NUM> is electronically calibrated, e.g. by systematic variation of the beam angle generated by the wearable ultrasound sensor <NUM> in order to detect an artery <NUM> of the patient in the Doppler ultrasound data generated with (acquired by) the wearable ultrasound sensor <NUM>. It is checked in operation <NUM> if such an artery <NUM> can be detected. If such an artery <NUM> cannot be detected, the method returns to operation <NUM> in which the caregiver manually repositions the wearable ultrasound sensor <NUM> after which its electronic calibration is repeated until the artery <NUM> is found after which the method proceeds to operation <NUM>.

In operation <NUM>, a region of interest close to the artery <NUM> is selected and in operation <NUM> a biplane view of the artery is generated to check alignment of the wearable ultrasound sensor <NUM> with the artery <NUM> in operation <NUM>. In operation <NUM>, the respective diameters of the artery <NUM> are evaluated systematically by manual repositioning of the wearable ultrasound sensor <NUM> by the caregiver in operation <NUM>, optionally aided by acoustic guidance signals generated by the alarm generating unit <NUM> until the maximum diameter of the artery <NUM> in both view planes is obtained, which is indicative of the optimal alignment of the wearable ultrasound sensor <NUM> with the artery <NUM>. Upon achieving such an optimal alignment, the method terminates in operation <NUM>.

<FIG> depicts a flowchart of a flowchart of a positioning and calibration method of the wearable ultrasound sensor <NUM>, here a <NUM>-D ultrasound sensor. The method in <FIG> differs from the method as shown in <FIG> for a <NUM>-D wearable ultrasound sensor <NUM> in that the manual repositioning of the wearable ultrasound sensor <NUM> in operation <NUM> to optimize the alignment of the wearable ultrasound sensor <NUM> with the artery <NUM> of the patient is replaced by operation <NUM> in which this repositioning is performed by electronic beam steering of the wearable <NUM>-D ultrasound sensor <NUM>.

The above described embodiments of the method <NUM> executed by the processor arrangement of the patient monitor control unit <NUM> may be realized by computer readable program instructions embodied on a computer readable storage medium having, when executed on the processor arrangement, cause the processor arrangement to implement any embodiment of the method <NUM>. Any suitable computer readable storage medium may be used for this purpose, such as for example an optically readable medium such as a CD, DVD or Blu-Ray disc, a magnetically readable medium such as a hard disk, an electronic data storage device such as a memory stick or the like, and so on. The computer readable storage medium may be a medium that is accessible over a network such as the Internet, such that the computer readable program instructions may be accessed over the network. For example, the computer readable storage medium may be a network-attached storage device, a storage area network, cloud storage or the like. The computer readable storage medium may be an Internet-accessible service from which the computer readable program instructions may be obtained. In an embodiment, the patient monitor control unit <NUM> is adapted to retrieve the computer readable program instructions from such a computer readable storage medium and to create a new computer readable storage medium by storing the retrieved computer readable program instructions in a data storage arrangement of the patient monitor control unit <NUM>, e.g. in a memory device or the like forming part of the patient monitor control unit <NUM>.

Claim 1:
A patient monitor control unit (<NUM>) comprising a processor arrangement (<NUM>, <NUM>) adapted to:
receive a series of ultrasound measurements received from a sensor (<NUM>), said sensor comprising at least one configurable ultrasound transducer;
process said series of ultrasound measurements to obtain haemodynamic data of a patient coupled to the sensor;
control a patient monitor (<NUM>) to display the obtained haemodynamic data;
evaluate the obtained haemodynamic data to detect a variance in said data; and
generate a reconfiguration signal for the at least one configurable ultrasound transducer, wherein the timing of said generation is a function of said evaluation.