NO346028B1 - Compact chest compression machine and its use - Google Patents

Description

Compact chest compression machine and its use

Purpose of the invention

Saturation divers, nationally and internationally, work with the installation, maintenance and repair of underwater equipment at great depths. The divers work from ships where they work, live and sleep under pressure, in pressure chamber systems, for several weeks at a stretch.

For example, at a depth of 180 meters (maximum ordinary depth in Norway). The ships then have a large pressure chamber system on board, and diving bells that are connected to the pressure chamber system. The divers move from the pressure chambers on the ship into the diving bell, all the time under the same pressure as the planned working depth on the seabed. The bell is then raised up and down to working depth, all the while under pressure.

If a saturation diver suffers a cardiac arrest while working on the seabed, he must be pulled into the diving bell, and the diving bell hoisted up to the pressure chamber system on the ship. This process takes about 15-30 minutes.

There is very limited space in a diving watch. Free floor space in the diving bell with full diving equipment is approximately 0.5 m in diameter. The inner diameter of the diving watch is generally somewhat smaller from the floor upwards due to hanging diving equipment. The patient cannot therefore be laid completely on the floor and there is no room to perform cardiopulmonary resuscitation (CPR) in a satisfactory manner. This means that in the event of a cardiac arrest, without adequate CPR, the diver will most likely not survive the transport from the seabed to the pressure chamber on the ship.

The invention relates to a compact chest compression machine which can make chest compressions possible in a diving watch. Compact chest compression machine consists of straps for fastening around the chest of divers with cardiac arrest, a piston for chest compressions and a control unit with an activation unit such as a push button driven by pressurized gas, such as air or heliox. Heliox is a mixture of oxygen and helium, which is the breathing gas in diving watches and pressure chamber systems.

When performing chest compressions on a patient, the first aider, when using the compact chest compression machine, only needs to activate an activation device, for example a button on the control unit. A push of a button activates the piston against the patient's chest, which thus replaces manual chest compression. The button is pressed and released for each compression. The first aider can stand near the patient, where there is free floor space, rather than taking up more floor space as in manual CPR without aids.

Background for the invention

There are several types of solutions for cardiac compression machines. The following solutions are highlighted with some similarity principles for the invention.

LUCAS™ with patent numbers US20100185127A1 and US20030181834A1 is described as a CPR device, released in several versions, of which some earlier versions are powered by gas. The latest version is powered by a motor and processor. The device consists, among other things, of a piston that automatically compresses the breast.

WO2005009318A2 is described as a heart compression device. The device consists of a mask for the supply of oxygen from propellant gas, a compressor and a piston for heart compressions.

NO133827B is described as a pneumatic heart compression device with a bed device to support the patient's upper part. The bed orientation has two belts, each with its own compression unit that compresses both the heart and the abdominal region of the patient.

The ROSC-U™ is described as an electromechanical chest compression device and has a portable power source as part of the system.

SCHILLER's EASY PULSE is described as mechanical HRL and is battery powered.

ZOLL's AutoPulse with patent number US8641647B2 is described as a resuscitation system with a back support structure and is battery powered.

Thumper device is described as a mechanical CPR machine powered by gas.

EP 2694011B1 describes a defibrillator tool in use with a processor for treating cardiac arrest with electromagnetic stimulation (on physiological tissue). The design consists of sensors in a vest/wide strap to be placed on the patient's skin. The patient's chest is stimulated via a sensor. Electromagnetic signals can be sent via magnetic stimulator system.

US6752771 is described as a method for a cardiac assistant using an inflatable vest for the treatment of heart failure. The system consists, among other things, of valves with monitor system, power source and compressor.

US9795532B2 is described as an automatic chest compression system consisting of a belt, inflatable bellows or piston for chest compression.

US2008/0097257A1 describes a resuscitation system with a chest compression unit. The system consists of processor, power and device to compress the chest.

US6676613B2 describes a cardiopulmonary resuscitation system that can be mechanically or electrically powered.

US3425409A describes a resuscitation process and resuscitation device with a manual chest compression tool and ventilator for air supply.

US20100198118A1 describes a tool with a belt for external cardiac massage.

US7846112 B2 describes a compression belt system with a platform for use with a chest compression unit.

US5287846A is described as a hydraulically powered piston and frame resuscitation unit.

US20150148717A1 is described as a CPR system with automated control unit and compression unit.

US20060047228A1 describes a CPR tool for facilitating cardiac compressions using mechanical force. The device is placed around the patient and must be activated manually for each compression on the device itself.

Patents and trademarks mentioned above are either too large in design and/or have too many parts to work together for use in a diving watch under high ambient pressure with high ambient humidity and in a heliox atmosphere.

Access to pressurized gas in the diving watch enables a compact design of the invention, because it removes the need for additional components such as an electric power source, compressor or gas in bottles. The invention should also allow the first aider to perform compressions in a standing position where there is free floor space. Furthermore, the invention must be compactly designed so that it takes up little space when stored.

In addition, the application description of the above-mentioned patents and solutions is mentioned only in the context of atmospheric air pressure at ground level, such as ambulances and hospitals.

The ambient pressure in a diving watch is significantly higher than on the surface.

The atmosphere in the diving watch consists of a mixture of helium and oxygen, instead of air, and is very humid, up to 90% humidity. The invention must therefore be able to be used regardless of ambient pressure, high humidity and salt water.

Short summary

Compact chest compression machine for compressions of the heart in confined spaces in an environment consisting of partially reused breathing gas, high ambient pressure and high ambient humidity, driven by pressurized gas, comprises a control unit (13) in the form of a control valve, hoses (11, 12, 15), connectors, a piston (1), a piston housing (4), a base plate, a metronome with light and speaker, and a ribbon (9).

Brief description of the drawings

Figure 1 shows the invention which consists of piston (1), piston foot (3), piston housing (4) with space for a metronome, band (9), base plate (5), band (9), hoses (11,12,15), and control unit (13).

Concrete examples

Figure 1 shows a piston housing (4) which can be square, cylindrical, oval or any other shape, made of solid material such as aluminum or hard plastic, where the piston (1) is centered. In or outside the piston housing (4), attached with a magnet or other attachment method, is an electric metronome, with a speaker for sound amplification, and which is connected to an electric light source. The metronome is programmed so that sound and light guide the compression beat. The piston housing (4) is further fixed in a bottom plate (5), made of solid material such as aluminum or hard plastic, where the bottom plate has a hole (6) for passage of the piston rod (2). The piston housing's bottom plate (5) also has through holes (7, 8) for the passage of inelastic tape (9) made of, for example, plastic, cotton or other wear-resistant material. The strap must be attached to the base plate using fastening methods such as spring-loaded buckles or Velcro. Parts of the belt can also be of rigid construction, for example plastic or metal with a hinge or telescopic rail, in order to take up less space during storage.

The piston (1) has a piston rod (2) with a sufficient stroke length, for example of 6-8 cm, to provide a compression between 5-6 cm in length towards the sternum region according to recommendations of the European Resuscitation Council. The end of the piston rod (2) is a piston foot (3) shaped like a hemisphere or similar shape with reduced internal material and a rounded surface so that it is somewhat hollow inside, made of rubber or other material with similar properties. The piston foot (3) must have a contact surface of around 5 cm in diameter when compressing the lower part of the patient's sternum.

The control unit (13) is a piston valve which consists of an activation unit (14) in the form of a button, lever or pedal to activate the piston (1). Due to the high ambient pressure in the diver's watch, the spring in the piston valve must have a greater force than the pressure from the environment in order to maintain the activation unit (14) in its normal position, that is, when the piston rod is in the piston housing.

For the transfer of pressurized gas into and exhaust from the piston, hoses (11, 12) are connected between the piston (1) and the control unit (13). It is also connected to a hose (15) which supplies pressurized gas from the system in the diving watch at approximately 10 bar to the control unit (13). The pressurized gas is transferred to the piston (1) by activating the activation unit (14), for example in the form of a button. By pressing the activation unit (14) and holding for 0.3 seconds and then releasing to the beat of the metronome, the force of (+/-5) 55kg from the piston should correspond to a chest compression on an adult person according to recommendation values from the European Resuscitation Council.

Alternatively, pressurized gas from gas cylinders, for example pressurized oxygen, can also be connected to the control unit (14), which is often found on helicopters, ambulances, in international health operations and defense operations. When using pressurized gas bottles, a regulator with manometer must also be included which must be connected to hose (15) to read and regulate the correct pressure into the control unit (13).

The piston can also be controlled by an automatic control system by replacing the valve piston with suspension (14) to an electromagnet valve connected to a programmed electronic control module stored in the piston housing (4).

The solenoid valve has an activation unit which can be a switch with several function selections, marked with for example; off, continuous and 30:2. Alternatively, the activation unit can also consist of several parts, for example a button for off, one for continuous and one for 30:2. The off function cuts off the power when the invention is not in use. The continuous function must be programmed so that the compressions are continuous. The 30:2 function must be programmed so that the compressions stop after thirty compressions, pause for a few seconds, and then start compressions again automatically. The pressurized gas can then be connected to the solenoid valve either from the diver's watch or from gas cylinders. By having a power source and a compressor that can deliver pressurized gas into the solenoid valve, the chest compression machine can also be a portable solution.

On the piston housing (4) is a simple user manual and guidance with figures and signs to clarify, among other things, the continuous function or the 30:2 function.

When stored, the invention must also take up little storage space, stored in a durable and moisture-resistant storage solution, for example in the form of a bag made of plastic or other similar solid material, or a box made of aluminum or other similar material.

Due to the fact that large parts of the breathing gas are reused in the diving watch, all compact chest compression components must consist of low-emission materials that emit little outgassing, such as aluminium, plastic and cotton. In order for the invention to work in an environment with high humidity in, for example, the diving watch, there must be gaskets and seals where there are connection points, for example on the ends of hoses. Certain surfaces must be treated with paint against corrosion that can occur from salt water in the diving watch.

The use of the invention

The piston (1) with the rod in the normal position is placed so that the piston foot (3) hits two finger widths above the tip of the sternum, in the middle of the sternum. The band (9) is tightened close to the patient so that the piston (1) with the piston foot (3) is firmly against the patient's body (3). The band (9) is locked with a fastening method such as spring-loaded buckles or Velcro to the bottom plate (9). Pressurized gas in the form of heliox from the diving watch is then connected to the control unit (13). When using compressed air bottles, a high-pressure hose (15) must be included with a regulator and manometer for connecting and reading the air supply from the bottles to the control unit (14). The metronome with magnet attached to the piston housing, can be removed and attached to the diving bell wall or a place that is easy to follow. Turning on a switch on the metronome activates it with sound and light. The light flashes in time with the sound to provide a compression beat if ambient noise drowns out the metronome's sound beat. The first aider holds and releases the activation device (14), for each compression, to the beat of the metronome for compressions on the patient.

When using a compact chest compression machine with an automatic control system, after placing the plunger and band on the patient, the high-pressure hose for pressurized gas must be connected to the solenoid valve. Then one of the activation units is activated, either the continuous function, or the 30:2 function, depending on whether the practitioner is a healthcare professional or not. The continuous function is intended for healthcare personnel, where they themselves turn on the off function after thirty chest compressions, activate the off switch to give breaths to the patient, and then activate the continuous function again. The 30:2 function is intended for users who are not certified healthcare personnel, where compressions stop automatically after thirty compressions, with the intention of giving time for inhalations on the patient, and then automatically start compressions again.

Claims (17)

Claim 1. Compact chest compression machine, for compressions of the heart in confined spaces in an environment consisting of partially reused breathing gas and high ambient pressure, powered by pressurized gas comprises a control unit (13) in the form of a control valve for controlling compressions, hoses (11, 12, 15) for transferring gas, connectors, a piston (1) for compressions on the chest region attached to a base plate (5), a piston housing (4), a band (9), and a metronome, characterized in that the metronome contains light and sound. 2. Compact chest compression machine according to claim 1, where the control unit (13) is a control valve with a spring for retraction of the piston rod (2) in the piston (1). 3. Compact chest compression machine according to claim 2, where the spring force in the control unit (13) for retracting the piston rod (2) is greater than the ambient pressure in the diving watch which is dependent on the diving depth. 4. Compact chest compression machine according to claim 1, 2 or 3, where the control unit (13) has an activation unit (14) such as a button, lever or pedal for manual activation of piston strokes corresponding to compression, characterized in that each compression is activated manually with the control unit. 5. Compact chest compression machine according to claim 1, 2, 3 or 4, where the control unit is connected to hose (15) for receiving pressurized gas. 6. Compact chest compression machine according to claim 1, 2, 3, 4 or 5, where the control unit (13) and piston (1) are connected to hoses (11, 12) for receiving pressurized gas and returning exhaust. 7. Compact chest compression machine according to claim 1,2,3, or 6, where the piston (1) is located in a piston housing (4). 8. Compact chest compression machine according to claim 1, where a piston foot (3) is hemispherical or similarly shaped, with a reduced internal volume and a rounded surface at the end, made of rubber or other materials with the same properties, is attached to the end of the piston rod (2 ). 9. Compact chest compression machine according to claim 1, where the piston housing is attached to the bottom plate (5). 10.Compact chest compression machine according to claims 1-9, where the piston (1) is attached to the bottom plate (5) with holes (6) for passage of the piston rod (2). 11. Compact chest compression machine according to claim 1 or 7, where the bottom plate includes holes (7, 8) for the passage of bands (9). 12.Compact chest compression machine according to claim 1 or 11, where the band (9) is attached to the bottom plate (5) with an attachment method. 13.Compact chest compression machine according to claim 1, 11 or 12, where parts of the band (9) can be rigidly constructed with a telescopic rail or hinge made of solid material such as metal or plastic. 14. Compact chest compression machine according to claim 1, 11, 12 or 13, where the belt otherwise has a softer construction of solid material such as plastic or cotton. 15. Compact chest compression machine according to claim 1, where the metronome is equipped with an electric light source and speaker. 16. Compact chest compression machine according to claims 1 and 15, where the metronome is electric and programmed for 100-120 sound and light beats per minute. 17. Compact chest compression machine according to claims 1, 15 and 16, where the metronome is stored in or on the piston housing (4) and is removable with a fastening device such as a magnet.