Patent Publication Number: US-2021186806-A1

Title: CPR Compression Device with Cooling System and Battery Removal Detection

Description:
FIELD 
     The inventions described below relate to the field of CPR chest compression devices. 
     BACKGROUND 
     Cardiopulmonary resuscitation (CPR) is a well-known and valuable method of first aid used to resuscitate people who have suffered from cardiac arrest. CPR requires repetitive chest compressions to squeeze the heart and the thoracic cavity to pump blood through the body. In efforts to provide better blood flow and increase the effectiveness of bystander resuscitation efforts, various mechanical devices have been proposed for performing CPR. In one type of mechanical chest compression device, a belt is placed around the patient&#39;s chest and the belt is used to effect chest compressions, for example our commercial device, sold under the trademark AUTOPULSE®. 
     These devices have proven to be valuable alternatives to manual CPR. The devices provide chest compressions at resuscitative rates and depths. A resuscitative rate may be any rate of compressions considered effective to induce blood flow in a cardiac arrest victim, typically 60 to 120 compressions per minute (the CPR Guidelines 2015 recommends 100 to 120 compressions per minute in adult victims), and a resuscitative depth may be any depth considered effective to induce blood flow, and typically 1.5 to 2.5 inches (the CPR Guidelines 2015 recommends 2 to 2.4 inches per compression in adults). 
     SUMMARY 
     It would be advantageous in a CPR chest compression device to provide for cooling of heat generating components such as the motor and the battery. The motor and battery both generate heat during operation the chest compression device, and it is advantageous to avoid excessive heating. The devices and methods described below provide for improved cooling in a CPR chest compression device. The chest compression device includes a housing configuration with baffles establishing a flow path over the battery and motor of the device, and exhaust fans which draw air from the vicinity of the motor to direct exhaust flow out of exhaust ports on the side of the housing. 
     On another front, it is advantageous to record operating data from the CPR chest compression device during use. This data may include the operating start times and stop times, battery life data or other battery metrics, compression rates, compression depths, total compressions applied and compressions pauses used, and other quality metrics. This data may be used for diagnosis of the patient, analysis of the effectiveness of compressions, and analysis of the operations of the chest compression device itself. Sudden loss of power to the control system can disrupt data collection, and result in loss of data collected, and it would be advantageous to prevent removal of the battery in order to replace it from causing loss of data. 
     The CPR chest compression device can include a compression device housing which houses various components including a drive spool and motor for rotating the drive spool, a motor with its motor housing, a fan disposed within the compression device housing, and a pathway for cooling airflow which includes an intake aperture and an exhaust aperture. The fan is disposed within the compression device housing, proximate a second end of the motor housing, between the second end of the motor housing and the exhaust aperture of the compression device housing, arranged to draw air from the second end of the motor housing and force air out the exhaust aperture of the compression device housing. The enclosure formed by the compression device housing may be configured with internal surfaces to direct air drawn by the fan through the compression device intake aperture, to an aperture in the motor housing. 
     The devices and methods described below provide for controlled shut-down of the CPR chest compression device when an operator attempts to remove the battery during operation, as might happen when the control system determines that the battery in use is nearing depletion or exhaustion, or the operator determines that a battery in use is nearing depletion or exhaustion. This is accomplished with a battery retainer mechanism, e.g., a latching mechanism, holding the battery in place, imposing an inherent short delay in removal, along with a detection mechanism which detects an attempt during the beginning of the removal process, with the control system programmed to recognize detection of a removal and operate to save data to a storage device, which may comprise fixed media, storage media, removable media, non-removable media, or memory including non-volatile memory and operate the system to ensure that the data is recoverable. 
     The CPR chest compression device can include a mechanism for detecting an attempt to remove its battery, and placing the control system in a safe condition, including completing the writing of collected patient and/or device data to a storage device, which may comprise fixed media, storage media, removable media, non-removable media, or memory including non-volatile memory, and/or ceasing further writing, before the battery is removed by a user. In a system where the control system is configured to control the chest compression device and write patient data and/or device data detected by sensors associated with the system to a storage device, a battery retainer may be configured to provide a signal to the control system indicating an attempt to remove the battery, and the control system can be correspondingly programmed to receive the signal and save data and cease writing data within a predetermined period which is shorter than the time required to complete battery removal. This system comprises a mechanical retaining structure for retaining the battery, configured to secure the battery to the chest compression device. The battery retainer may be operable by the user to release the battery from the chest compression device, wherein operation by the user to release the battery from the chest compression device requires moving the mechanical retaining structure through a range of motion, including an initial range of motion less than a full range of motion required to release the battery from the chest compression device. A sensor for detecting a motion of the mechanical retaining structure at a point in the range of motion prior to release of the battery (an initial range of motion), and the sensor operable to generate a signal indicative of said motion and transmit said signal to the control system. The control system is operable to receive the signal indicative of the motion and is programmed to cease writing patient data and/or device data to the storage device upon receiving the signal indicative of said motion. e the control system may be operable to (1) complete any writing in progress when the signal indicative of the motion is received, and (2) cease further writing of patient data and/or device data to the storage device upon receiving the signal indicative of the motion, within the predetermined time period, and the battery retainer is further configured such that the time required for a user to move the mechanical retaining structure from the initial range of motion through the full range of motion exceeds the predetermined time period. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  illustrates the CPR chest compression device installed on a patient. 
         FIG. 2  is a perspective view of the CPR chest compression device, illustrating the cooling intake baffles and outlet baffles within of the housing. 
         FIG. 3  is a perspective view of the CPR chest compression device, illustrating the apertures in the housing for cooling flow exhaust. 
         FIG. 4  is an anterior view of the CPR chest compression device, illustrating the cooling intake baffles and outlet baffles within of the housing. 
         FIG. 5  is a top/superior view of the CPR chest compression device, illustrating the cooling intake flow path between the housing baffles and the battery. 
         FIGS. 6 through 10  illustrate the operation of the battery disconnection detection mechanism which detects an attempt to remove the battery and saves various data upon detection during a short period required for an operator to complete actions required to remove the battery. 
     
    
    
     DETAILED DESCRIPTION 
       FIG. 1  shows a chest compression device fitted on a patient  1 . The chest compression device  2  applies compressions with the compression belt  3 . The chest compression device  2  includes a belt drive platform  4  sized for placement under the thorax of the patient, upon which the patient rests during use and which provides a housing  5  for the drive train and control system for the device. The control system, provided anywhere in the device, can include a processor and may be operable to control tightening or loosening operation of the belt and to provide output on a user interface disposed on the housing. Operation of the device can be initiated and adjusted by a user through a control panel  6  and/or a display operated by the control system to provide feedback regarding the status of the device to the user. The control system is configured to control the device to perform repeated compression cycles when the device is fitted about a patient&#39;s chest. A compression cycle includes a downstroke, an upstroke (a release portion), and perhaps some delay between a downstroke and a successive upstroke, or between an upstroke and a successive downstroke. In the operation of the AUTOPULSE® chest compression device, the system operates to take up slack in the belt upon initial start-up, equates the rotational position of the drive spool at this point as the slack take-up position, and begins each downstroke from this position. 
     The belt includes a wide load-distribution section  7  at the mid-portion of the belt and left and right belt ends  8 R and  8 L (shown in the illustration as narrow pull straps  9 R and  9 L), which serve as tensioning portions which extend from the load distributing portion, posteriorly relative to the patient, to drive spools within or on the housing. When fitted on a patient, the load distribution section is disposed over the anterior chest wall of the patient, and the left and right belt ends extend posteriorly over the right and left axilla of the patient to connect to their respective lateral drive spools shown in  FIG. 2 . 
       FIGS. 2 and 3  shows the CPR chest compression device in isolation.  FIG. 2  provides a view of the device with the housing anterior surface hidden. As illustrated in  FIG. 2 , drive spools  10 R and  10 L are disposed laterally on either side of the housing. The belt pulls straps  9 R and  9 L (shown in  FIG. 1 ) are secured to these drive spools, locked into channels  11  running longitudinally along the drive spools. The lateral drive spools are in turn driven by a motor  12  also disposed within the housing, through a motor shaft  13 , a transmission  14 , a drive shaft  15  and drive belts  16 R and  16 L. The belt pull straps  9 R and  9 L are attached to the lateral drive spools such that, upon rotation of the drive spools, the pull straps  9 R and  9 L are pulled posteriorly, spooled upon the lateral spools, thereby drawing the compression belt downward to compress the chest of the patient. 
     Features of the ventilation system are also illustrated in  FIG. 2 . The motor  12  is disposed within a motor enclosure bounded by side walls  17 R and  17 L and an inferior wall  18 , and a superior wall  19 . An inlet to the motor compartment is provided by one or more motor compartment inlet apertures  20 . (The motor compartment inlet aperture may be the same as the chest compression housing intake aperture  27 .) An outlet for the motor enclosure is provided by an exhaust aperture  21 . An exhaust fan  22 , proximate the exhaust aperture, is operable to draw air from the motor enclosure and force it out of the motor enclosure through the exhaust aperture. The motor itself is characterized by a motor housing, a first end  23  and a second end  24 , with the motor shaft  13  disposed at the second end, and a motor housing inlet aperture  25  in the motor housing proximate the first end, and a motor housing outlet aperture  26  in the motor housing proximate the second end. 
     The compression device housing is configured to support the patient during operation of the CPR compression device, and also forms an enclosure substantially enclosing the motor. The compression device housing has an intake aperture  27  for intake of cooling airflow and exhaust aperture  28  for exhaust of cooling airflow. An inlet aperture and an exhaust aperture may be provided on each side of the device. 
     The fan  22  is disposed within the compression device housing, proximate the second end of the motor housing and between the second end  24  of the motor housing and the exhaust aperture  28 . The fan is arranged to draw air from the second end of the motor housing and force air out the exhaust aperture of the compression device housing. Alternatively, the fan can be reversed, to draw or force air into the second end of the motor and out of the first end of the motor, or draw air from aperture  28  and force air out of aperture  27 . The fan and/or exhaust aperture may instead be disposed at the first end of the motor with an intake aperture proximate the second end of the motor housing, and may also be integral to the motor. One fan may be used on each side of the housing, as shown, or a single fan may be used. The control system may control the fan(s) to operate continuously, or intermittently as necessary to cool the device, independent of the operation of the motor. 
     Further referring to  FIG. 2  and  FIG. 4 , to provide cooling flow to the battery, the compression device housing can be configured so as to place the battery in the cooling flow pathway. The battery  29  fits in a battery compartment  30  bounded by side walls  31 R and  31 L and an inferior wall  32 , with an aperture  33  leading to the motor housing, and an intake aperture  34  formed in the superior surface  35  above the battery which allows for insertion and removal of the battery. The superior intake aperture in this embodiment is in fluid communication with s the housing intake aperture  27  identified above. (This superior aperture may be a gap between a battery cover and the compression device housing, as illustrated below, or a gap in the battery cover.) The battery is configured relative to the battery compartment so as to define a flow path for air from the intake aperture  34  of the compression device housing to the first aperture of the motor housing. The battery may be sized relative to the battery compartment so that the flow path is defined between a surface of the battery and an internal surface of the compression device housing, or the battery may be configured with a channel running through the battery, so that the channel defines the flow path. 
     The various walls and surfaces may be disposed within the compression device housing, between the intake aperture of the compression device housing and the first end of the motor housing, configured to serve as baffles to direct air drawn by the fan through the intake aperture of the compression device housing to the motor, including to the first aperture of the motor housing (with the configuration adjusted depending on whether the motor housing first aperture is also the intake aperture of the compression device housing, or the motor housing first aperture is downstream from the battery disposed between the motor and the intake aperture of the compression device housing. The intake aperture of the compression device housing may be located in the compression device housing such that it sits behind the battery (when the battery is inserted into the chest compression device), with a gap remaining between the intake aperture of the chest compression device and the battery cover, to allow for the flow/passage of air. This positioning of the compression device intake aperture helps protect or shield the compression device intake aperture from being blocked or obstructed, which could result in the overheating of or damage to the motor and compression device. The location of the intake aperture may be recessed relative to a posterior surface of the chest compression device housing. 
     Other walls that separate the battery compartment from the first end of the motor, disposed between the intake aperture of the compression device housing and the first motor end, having an aperture communicating from the battery compartment to the first end of the motor, define a second baffle within the compression device housing. The enclosure formed by the compression device housing is configured with internal surfaces to direct air drawn by the fan through the intake aperture of the chest compression device housing, to the first aperture in the motor housing (if they are distinct) and further configured with internal surfaces to direct air drawn by the fan from the second aperture in the motor housing, through the fan, and out the exhaust aperture. The battery compartment internal surface may also be configured to prevent air drawn by the fan through the intake aperture of the compression device housing from flowing through the battery compartment along pathways not at least partially defined by the battery configured for insertion into the battery compartment. 
     Various motors may be utilized, e.g., the motor may be a brushed DC motor, with a commutator and brush assembly disposed at the first end (opposite the motor shaft). 
       FIG. 3  is a perspective view of the CPR chest compression device, illustrating the apertures in the compression device housing which provide for access to the drive spool for connecting the belt to the drive spool. The apertures  36 R and  36 L on either side of the housing are disposed proximate the drive spools. The apertures are sized to allow passage of the belt end through the housing wall for insertion into the drive spools. The apertures can extend over the housing anterior surface  5 A and lateral surface  5 L as shown, or over the housing anterior surface  5 A alone, or the lateral surface  5 L alone, to preferably provide access to the drive spools from an anterior approach or lateral approach even while a patient is disposed on the anterior surface. Spindles  37 R and  37 L may be provided to guide the belt ends through the apertures. 
       FIG. 3  also illustrates the position of the exhaust apertures  28  of the housing, which, in this embodiment, are distinct from the apertures used to access the drive spools. The drive spool apertures are isolated from the ventilation flow by the inferior wall  18  of the motor compartment. 
     The several apertures, including the compression device housing intake aperture  27 , the compression device housing exhaust aperture  28 , and the motor compartment inlet aperture  20  or the motor compartment exhaust aperture  21 , can be covered with a hydrophobic mesh. 
       FIG. 4  is an anterior view of the CPR chest compression device, illustrating the cooling intake baffles and outlet baffles within of the housing. This figure more clearly shows the location of the motor enclosure side walls  17 R and  17 L, inferior wall  18 , superior wall  19 , motor compartment inlet aperture  20  and motor compartment exhaust aperture  21 . Portions of the motor include the motor first end, motor second end, and the motor housing inlet aperture  25  in the motor housing proximate the first end, and a motor housing outlet aperture  26 . The compression device intake aperture  27  and exhaust aperture  28 , and the fan  22  are also shown. The walls  31 R,  31 L and  32  of the battery compartment  30  are also shown in this view. 
       FIG. 5  is a top/superior view of the CPR chest compression device  2 , illustrating the cooling intake flow path between the compression device housing baffles and the battery. This view shows the battery  29  within the battery compartment  30 , bounded by the side walls  31 R and  31 L. The small gaps  38  between the battery and the walls of the battery compartment provide a flow path for cooling air over the battery. 
     The CPR chest compression device can include a mechanism for detecting an attempt to remove its battery, and placing the control system in a safe condition, including completing the writing of collected patient and/or device data to a storage device, and ceasing further writing, before the battery is removed, or electrically disconnected by a user. In a system where the control system is configured to control the chest compression device and write patient data and/or device data detected by sensors associated with the system to a storage device, a battery retainer may be configured to provide a signal to the control system indicating an attempt to remove the battery, and the control system can be correspondingly programmed to receive the signal and save data and cease writing data within a predetermined period which is shorter than the time required to complete battery removal or move the battery sufficient to electrically disconnect the battery from the compression device. This system comprises a retaining structure, e.g., mechanical, for retaining the battery, configured to secure the battery to the chest compression device. The battery retainer may be automated or manually operable by the user to release the battery from the chest compression device. In certain embodiments operation by the user to release the battery from the chest compression device may require moving a mechanical retaining structure through a range of motion, including an initial range of motion less than a full range of motion required to release the battery from the chest compression device. A sensor for detecting a motion of the retaining structure at a point in the range of motion prior to release of the battery (an initial range of motion), and the sensor operable to generate a signal indicative of said motion and transmit said signal to the control system. The control system is operable to receive the signal indicative of the motion and is programmed to cease writing patient data and/or device data to the storage device upon receiving the signal indicative of said motion. The control system may be operable to (1) complete any writing in progress when the signal indicative of the motion is received, and (2) cease further writing of patient data and/or device data to the media upon receiving the signal indicative of the motion, within the predetermined time period. The battery retainer may be further configured such that the time required for a user to move the retaining structure from the initial range of motion through the full range of motion exceeds the predetermined time period. 
       FIGS. 6 through 10  illustrate the operation of such a battery disconnection detection mechanism which detects an attempt to remove the battery and saves various data upon detection during a short period required for an operator to complete actions required to remove the battery. The chest compression device includes a control system operable to control operation of the chest compression device to perform repeated compression cycles when the device is fitted about a patient&#39;s chest, and also to collect patient data and/or device data (such as the operating start times and stop times, battery life, compression rates, compression depths, total compressions applied and compressions pauses used, and other quality metrics) detected by sensors associated with the system to a storage device. In such a device, it would be advantageous to detect an attempt to remove the battery and, in response to this detection, operate the control system to save collected data to the storage device and cease writing to the storage device, and optionally inhibit the removal of the battery until the control system has completed these tasks. 
       FIG. 6  is a superior view of the CPR chest compression device  2  showing a battery cover  51  which covers and retains the battery in the battery compartment. The cover is shown in isolation in  FIGS. 7 through 10 . The battery cover includes battery retainer components interoperable with battery retainer components, in the housing. The battery retainer components may include a fastener, latch, clip, clamp or other fastening or latching connection mechanism. The battery cover may further include an operating mechanism (e.g., manual or automated) configured to detect an action required for battery removal, generate a signal corresponding to detection of the action required for removal and transmit this signal to the control system, and require a further action to remove the battery. The further action may require a period of time, between initiation and completion, sufficient for the control system to save data generated by other components of the system to a storage device, such that the data is saved to the storage device before the battery is removed. The battery cover shown in  FIGS. 6 through 10  is an example of such a system. The components of the battery cover can be applied directly to the battery, or the battery cover can be fixed to the battery, or, as illustrated, the battery cover can be provided as a discrete component separate from the battery. As shown in  FIG. 7 , the cover includes a manually-operated actuator  52 , operable by the operator to force a cam plate to rotate, and thus force the battery retainer component, which is a latch component in this example, downwardly (posteriorly, in relation to a patient to which the CPR compression device is attached). As shown in  FIG. 8 , the cover includes one or more latch components  53  which are configured to engage with corresponding latch components in the housing  5 . The latch components are biased toward an engaging position by springs  54  or other biasing mechanism. A cam plate  55  with a first cam lobe  56  which is located on the cam so as to impinge on a contact switch  57  when rotated through a first arc. 
     The cam plate may include a second cam lobe  58 , not co-planar with the first cam lobe  56 , near a follower  59  fixed to the latch component  53 , such that rotation of the cam plate (through a second arc, greater than the first arc) results in impingement of the lobe on the follower, and thus forces the latch component to move away from the center of the cam plate, and thus, in the illustrated configuration, downwardly against the force of the springs and out of engagement with the latch component(s) on the housing. The first cam lobe  56  acts on the contact switch  57  at a first radial position on the cam plate, and the second cam lobe  58  acts on the latch mechanism follower  59  (or directly on the latch mechanism) at a second radial position on the cam plate. The sensor is substantially co-planar with the first cam lobe and the first latch component (the latch component  53  or its associated follower  59 ) is substantially co-planar with second lobe of the cam plate. The first radial position is displaced (advanced) around the cam lobe, in the direction of rotation of the cam plate, relative to the second position, such that the first cam lobe makes contact with the contact switch before the second cam lobe forces the cam follower downwardly to the extent necessary to force the latch component downwardly and out of engagement with the latch components on the housing. The control system of the device is operable to detect contact between the first cam lobe and the contact switch, and it is programmed such that, upon detection of contact between the first cam lobe and the contact switch, the control system will operate to save any patient data and/or device data collected by sensors associated with the system to storage device. This can be accomplished by the control system in a short period of time, before an operator can further rotate the actuator to the extent necessary to bring the second cam lobe into impingement with the cam follower to the extent necessary to force the latch component downwardly and out of engagement with the latch components on the housing. 
     When the battery is locked into the housing, the cam plate is positioned relative to the contact switch and follower as shown in  FIG. 8 , where the first cam lobe is arcuately displaced from the contact switch, and the second cam lobe is arcuately displaced from the follower. As shown in  FIG. 9 , when the operator rotates the cam plate through a first arc, the first cam lobe is arcuately aligned with the contact switch, while the second cam lobe is still arcuately displaced from the follower, so that the contact switch is actuated but the latch components are not moved. As shown in  FIG. 10 , upon further rotation of the cam plate, the second cam lobe rotates into alignment with the follower to force the follower and latch component downwardly. 
     The battery removal detection mechanism and sensor can be implemented in many ways. The contact switch is just one of many means or mechanisms for detecting operator action preceding battery removal. Other such means or mechanisms can include any form of contact or proximity sensor operable to sense proximity of the cam lobe with the sensing component, or any inductive sensor operable to detect operator contact with the actuator or any inductive sensor operable to detect motion of the actuator, including contact switches, contact relays, magnetic sensors, capacitive sensors inductive sensors, optical sensors, photocells, ultrasonic sensor, or any other means for sensing movement of the actuator. Sensors may include a first sensor component and second sensor component, e.g., a sensor target and a sensing component operable to sense the movement of the sensor target, and either sensor component may be disposed on the actuator or on the battery cover (or elsewhere on the device). A relay switch may comprise an electromagnetic switch operated by a small electric current, with a magnet or electromagnet on one structure (the cam or the cover) and a spring-loaded switch on the other structure, where proximity of the magnet or electromagnet functions to close or open the spring-loaded switch. A change in the switch position may be taken by the control system as a signal indicative of movement of the actuator. A contact switch may comprise a switch on one structure (the cam or the cover) activated by contact with an impinging component on other structure. For example, a reed switch disposed on the cover, operable to be closed by a protrusion on a cam lobe, when the cam is rotated. Closure of the switch may be taken by the control system as a signal indicative of movement of the actuator. A magnetic sensor may comprise a Hall effect sensor on one structure (the cam or the cover), and a magnet on the other structure. Detection of the magnetic field of the magnet may be taken by the control system as a signal indicative of movement of the actuator. A capacitive sensor may comprise a capacitive sensor probe with a sensing electrode on one structure (the cam or the cover), and a conductive target, or a capacitive sensor probe on one structure, combined with a conductive target on the same structure on the opposite side of a channel which accommodates the other structure, operable to sense the entry of other structure (whether conductive or non-conductive) by its effect on the capacitance measured by the capacitive sensor probe. Detection of the target may be taken by the control system as a signal indicative of movement of the actuator. An inductive sensor may comprise a magnetic field oscillator on one structure (the cam or the cover), and a conductive target on the other structure. Detection of a change in the amplitude of the oscillator may be taken by the control system as a signal indicative of movement of the actuator. An optical sensor may comprise photoelectric detectors and optical encoders. Optical encoders, for example, may comprise and encoder scanner on one structure (the actuator or the cover), and an encoder scale on the other structure. Detection of the encoder scale by the encoder scanner may be taken by the control system as a signal indicative of movement of the actuator. A photoelectric sensor may comprise an emitter light source on one structure (the actuator or the cover), and a photodetector the other structure (or a reflector on the other structure and a photodetector on the first structure). Detection of light, or loss of detection of light, from the emitter light source by the photodetector may be taken by the control system as a signal indicative of movement of the actuator. An ultrasound sensor may comprise a transducer on one structure (the actuator or the cover), and a reflective target on the other structure (the structure itself may constitute the target), in a through-beam or reflective arrangement. Detection of light reflected by the target, or alteration of the light by transmission through the target may be taken by the control system as a signal indicative of movement of the actuator. 
     The battery retainer components may take many forms as well. The latch component for engaging the housing is just one of many latching or fastening mechanisms for securing the battery cover to the housing. Other such mechanisms can include any form of latching or fastening mechanism, including clamps, clips or restraints, a compression latch (pinching actuation), a push button, or pull-out feature mechanism, manually operated or automatically operated by the control system upon input from the user. 
     The battery cover is just one example of a battery retainer or battery hold-down that may be configured to hold the battery physically in place relative to the housing and in electrical communication with the control system and motor of the chest compression device. Many retaining structures may be used to lock the battery in place, without also serving to cover the battery and protect it from the environment outside the battery compartment. The retainer may comprise a toggle switch or clamp, a rotatable catch fixed to the battery or chest compression device, a drawer lock fixed to the battery or chest compression device, a rotatable threaded lid, a detent pin or ball locking pin. 
     Various patient and/or device data may be collected by the battery and/or chest compression device as discussed herein. Such data may be recorded and/or transmitted to a remote server or device, allowing for remote management of device or patient data. Exemplary data includes device performance data, such as compression fraction (the amount of time compressions were delivered during a CPR event); compression rate; compression depth; the frequency with which the device met a target depth; device self-test results; fault codes; battery performance; and predictive failure codes or check engine light codes (e.g., battery life or faulting). 
     Device and battery data may be transmitted in the following ways: Data from the compression device may be transmitted to the battery. The battery may be placed in a charger and data may be transferred from the battery (or the compression device) to the cloud or remote server. A user/manager may log in to their account via the internet to retrieve their device or battery data, e.g., to review their device performance and device data and/or to remotely manage or monitor their devices/assets. A user/manager may monitor chest compression device usage, battery life, etc. Alternatively, a user/manager may retrieve data directly via a USB port or other port present on the device or charger. Data may be transmitted to the cloud or remote server from the battery while the battery is charging. 
     While the preferred embodiments of the devices and methods have been described in reference to the environment in which they were developed, they are merely illustrative of the principles of the inventions. The elements of the various embodiments may be incorporated into each of the other species to obtain the benefits of those elements in combination with such other species, and the various beneficial features may be employed in embodiments alone or in combination with each other. Other embodiments and configurations may be devised without departing from the spirit of the inventions and the scope of the appended claims.