BR102020008534A2 - IMPROVEMENT INTRODUCED IN HYBRID ARTIFICIAL RESPIRATOR WITH REMOTE CONTROL, WITH MONITORING SYSTEM, DATA STORAGE AND MISCELLANEOUS MEASUREMENTS - Google Patents

Abstract

improvement introduced in a hybrid artificial respirator with remote control, with a monitoring system, data storage and various measurements. comprised of a breather, formed from a casing whose front section describes a window, provided with a cover provided on the side with reliefs and internally houses a pumping device formed by a sliding assembly, whose front face in the lower section holds a seating base, above which extends a cradle that describes a concave packaging base, which receives an ambu bag that is pressed by a sliding vise plate, the upper section being equipped with a bearing support, while the rear face projects below a support that accommodates a motor. step, which receives the coupling of a threaded spindle that moves through a nut the support plate fixed to said sliding vise plate, the spindle being fixed above the closing plate of the bearing support, the breather is controlled by software that allows the pressure to be measured , in addition to sensors to control flow, oxygen and heart rate, through a control panel.

Description

IMPROVEMENT INTRODUCED IN HYBRID ARTIFICIAL RESPIRATOR WITH REMOTE CONTROL, WITH MONITORING SYSTEM, DATA STORAGE AND MISCELLANEOUS MEASUREMENTS

001 This patent application refers to an "IMPROVEMENT INTRODUCED IN A HYBRID ARTIFICIAL RESPIRATOR WITH REMOTE CONTROL, WITH MONITORING SYSTEM, DATA STORAGE AND MISCELLANEOUS MEASUREMENTS" which was developed with the purpose of providing artificial ventilation, in cases of respiratory failure, by pressing the internal ambu bag by the flap backed by a mechanical module with spindle, guides and stepper motor; capable of remote monitoring and command of respiratory settings and storage of patient data in the cloud, as well as blood pressure measurement , oxygenation, temperature and heart rate.

State of the Art

002 The critical role of the lungs in sustaining life is well known - most people are aware of the body's need for oxygen to maintain cellular metabolism and recognize the critical role of the lungs in providing the necessary amounts of oxygen to sustain life. When breathing stops, as it does during cardiac arrest, a vicious circle of events occurs when the body's cells try to survive without the oxygen needed for metabolism. These events constitute the initial phase of biological death, which progresses rapidly without immediate emergency treatment.

003 Consequently, one of the first priorities in resuscitation is to establish a means of providing artificial ventilation to the patient. This starts with what is known in the art as establishing an airway, which is the process of providing an open passageway for air to travel through the patient's mouth, throat, and trachea to the lungs.

004 Artificial respiration can be achieved using the mouth-to-mouth procedure, or through the use of devices.

005 One such device is the ambu bag. The ambu bag, which is a self-inflating bag, made of latex or silicone, commonly used to provide positive pressure ventilation to patients with respiratory difficulties. It is light, transportable and easy to use.

006 Such a manual resuscitator was originally designed in the 1930s and, over the years, has strengthened its position as the first-line device employed in artificial ventilation. The balloon-style design is inherently intuitive - little training is required to learn how to operate the device, and its simplicity makes it ideal for use in the frantic environments commonly associated with resuscitation efforts. Its simple design also makes it inherently reliable - another highly desirable attribute for an essential resuscitation medical device. Finally, the cost of manual resuscitators is very low, enabling them to be readily stored in easily accessible locations throughout the hospital.

007 With these strong attributes intrinsic to the hand-held respirator's basic design, little has been done over the years to modify it. Improvements included the use of new materials in the construction of the flexible fluid chamber to facilitate a better, more comfortable grip. Other design refinements have lightened weight and lowered manufacturing costs, further contributing to the savings on disposable versions of the device.

008 Although the ambu bag can be pressed manually, the use of mechanical devices that aid in compression is highly recommended, as the human hand is tired and is not able to accurately control the respiratory rate, air volume, pause and the pressure sent to the lungs. For this reason, it uses artificial respirators, which are devices that, in essence, compress the ambu bag, taking air to the lungs.

009 There are several artificial respirators on the market that work by compressing the ambu bag. They are electrical equipment that base their operation on “arms” that press laterally on the ambu bag, expelling compressed air or enriched with oxygen, supplying the patient's respiratory deficiency. Examples of artificial respirators that use the ambu bag are US patents D666,299 S and US 8,235,043 B2.

010 The artificial respirator based on the ambu bag can be of the "simple" category, where the only source of the air pressed by the ambu bag is the ambient air, or it can be of the "hybrid" category, which, in addition to ambient air, can be enriched simultaneously with an exogenous oxygen line.

011 Artificial respiration can be of the “invasive” category, where the patient is intubated, or the “non-invasive” category, where the patient only wears an external mask on their face.

012 The artificial respirator is equipment that, on many occasions, and not just in emergencies, needs to work uninterruptedly for weeks, since any break represents a clear risk to the patient's health.

013 Only the most complex and expensive artificial respirators, powered by piston compression (that is, they do not use the ambu bag), have sensors with different operating modes, which can measure the pressure and volume of air entering or leaving the lung of the patient, the inspiratory and expiratory rate and assist in the respiratory cycle, among other measurements.

014 The importance of using an artificial respirator has become even more evident as a result of the Covid-19 virus (Corona virus) pandemic, a disease that directly attacks the lungs. The seriously ill by the Covid-19 virus are forced to remain in hospitals for weeks, intensively using the artificial respirator. One of the most common complications in Covid-19 is the acute respiratory distress syndrome, which requires both the use of mechanical ventilation with high inspired oxygen fractions. It is caused by viral replication in lung cells, which reduces the organ's functional capacity.

015 The use of artificial respirators often occurs in hostile environments, such as rescue operations, ambulances, battlefields, field hospitals, in remote indigenous tribes within forests, etc., different from the sterile, close and calm environment of a hospital, where the robustness of the device and its remote monitoring gain relevant importance.

016 Thus, against the intensive use of such equipment, every artificial respirator should be made with long-lasting parts and materials, avoiding material fatigue, as well as having the ability to control by a specialist doctor at a distance and devices for measurement of blood pressure, temperature and heart rate.

017 Patent PI 9903858-7 deals with equipment intended for artificial ventilation in case of respiratory failure, being designed in a small size monobloc, which makes it much more resistant, easy to assemble, with reduced manufacturing cost and no empty spaces, where debris or dust normally accumulates, facilitating possible contamination, its cycling system is composed of only one moving part, which is a rubber diaphragm with a special design, with a flexible central part, where in the center of its underside there is a ring-shaped relief, which cyclically seals the source gas inlet orifice, on the other hand, without friction by sliding at any point, which avoids wear with operation, a helical spring supported on its upper face inside a small chamber (2.5 cm^ 3Λ), whose gas inlet and outlet are made by only a needle valve that controls the two phases of the respiratory cycle and consequently the frequency of the device, presented as special features the generation of a square wave with high frequency response with the consumption of a small volume of gas (chamber volume per cycle); it is therefore a highly reliable and secure equipment.

018 Patent PI 0200328-7, on the other hand, is indicated for cases of acute or chronic respiratory failure, in short lung ventilation, for transporting patients and in intra-hospital procedures such as Intensive Care Centers and emergency rooms, or in extra transport -hospital when adapted in ambulances or helicopters, especially in patients with lungs with little change and in breathing exercises where intermittent positive pressure is indicated, basically comprising a set of logical cells where the pressurized air is connected to a cylindrical chamber (1) that contains a moving discoid part (2) that seals the gas outlet hole in the central part of the chamber (1), and in the center of this discoid valve (2) there is a guide rod (3) that is housed in this hole (4) .

019 The objective of the present invention is an equipment mechanically activated by a threaded spindle, which gives it greater strength, if compared to other artificial respirators based on pulleys, pulleys, belts or gears.

020 Another objective of the present invention is a hybrid artificial respirator, as its feeding occurs only with ambient air (which contains oxygen), or through resources that are available (oxygen line or other gases), acting not only as a respirator, but also assisting in other medical procedures (anesthesia, for example).

021 Another objective of the present invention is an artificial respirator that can be used invasively (when the patient is intubated) or non-invasively (when the patient only wears the mask on their face).

022 Another objective of the present invention is an artificial respirator that contains a generalist circuit board, a WiFi/Bluetooth network card and software (computer program and application for cell phones) capable of remotely controlling the flow rate, pressure and pace of breathing, as well how to store patient health data in the cloud.

023 Another objective of the present invention is an artificial respirator that also contains internal devices for measuring blood pressure, oxygenation, body temperature and heart rate of the patient who is undergoing artificial respiration.

024 Another objective of the present invention is an artificial respirator actuated by a threaded spindle that provides a mechanical actuation with less friction, without losing the compressive strength, providing greater robustness to the equipment, preventing breakages during the treatment of the patient, which could represent their death.

025 In order to obtain a perfect understanding of what has been developed, illustrative drawings are attached to which numerical references will be made together with a detailed description, where:
Figure 1 shows a view of the respirator with the ambu bag.
Figure 2 shows a perspective view of the respirator.
Figure 3 shows an exploded front perspective view of the respirator.
Figure 4 shows an exploded rear perspective view of the respirator.
Figure 5 shows a front perspective view of the slide assembly.
Figure 6 shows a rear perspective view of the slide assembly.
Figure 7 shows an exploded perspective view of the slide assembly. As illustrated in the figures and in their details the "IMPROVEMENT INTRODUCED IN A HYBRID ARTIFICIAL RESPIRATOR WITH REMOTE CONTROL, WITH MONITORING SYSTEM, DATA STORAGE AND MISCELLANEOUS MEASUREMENTS" comprised of a respirator (1), formed from a housing (2), whose front section (3) describes a window (4), provided with a front cover (5) provided laterally with reliefs (6) and a rear cover (5'), and internally accommodates a pumping device (7) formed by a sliding assembly (8), whose front face (9) in the lower section (10) holds a base (11), above which extends a cradle (12) that describes a concave conditioning base (13), which receives an ambu bag (14) which is pressed by a sliding vise plate (15), the upper section (16) being provided with bearing support (17), while the rear face (18) projects a support below (19) that accommodates a stepper motor (20), which receives the coupling of a threaded spindle (21) that moves up to through a nut (22) the support plate (23) is fixed to said sliding vise plate (15), the spindle (21) being superiorly fixed to the closing plate (24) of the bearing support (17), breather (1) is commanded by a software that allows measuring the pressure, in addition to sensors to control the flow, oxygen and heart rate, through a control panel (25).

026 Based on the above, we can see that the "IMPROVEMENT INTRODUCED IN A HYBRID ARTIFICIAL RESPIRATOR WITH REMOTE CONTROL, WITH MONITORING SYSTEM, DATA STORAGE AND MISCELLANEOUS MEASUREMENTS" brings great advantages, which are: (a) to provide uniform and predictable compression of the ambu bag without taking into account the positioning of the hands, the size of the operator's hands or the use of one or two hands for operation; (b) provide variable rates of air displacement, depending on the volume delivered, whereby smaller volumes intended for infants and pediatric patients require greater relative movement of the ambu bag (providing greater accuracy) compared to larger volumes supplied to adult patients; (d) providing an increased flow rate when used in adult patients, where low flow rates are provided at the beginning of the breath and slowly increase towards the end inspiration, which improves the distribution of gas in the lung; (e) systematically supply, complete, and uniform tidal volumes, without regard to technique, thus allowing the physician to prescribe a specific and predictable degree of ventilatory support adapted to the specific physical attributes of the patient and the underlying disease; (f) provide safeguards to prevent harm to the patient caused by excessive release of airway pressures and flow rates; (g) allow the assertive delivery of large tidal volumes without compromising patient safety, providing safer and more effective ventilation; (h) provide consistent volumes with each breath, increasing the uniformity of airway pressures detected by the operator and therefore the ability to progressively detect increased airway resistance, which also increases the clinical applicability of certain monitoring tests ; (i) provide the ability to prescribe a specific maximum airway pressure to which the patient will be exposed.

027 It should also be noted that the vertical activation of the mechanical assembly, pressing the ambu bag from top to bottom, allows the device to have a smaller size than if it were horizontally, facilitating transport and storage inside an ambulance or infirmary.

028 The respirator has the ability to adapt to the compass, flow, pressure, increments and deductions pre-configured by a medical team, a facility such that it allows for safe operation, without necessarily having the presence of an expert professional on site, sending and storing in " cloud” the patient's health data, giving doctors access to the entire history, which gives them great decision-making power.

029 The respirator has a blood pressure, oxygenation, temperature and heart rate meter, helping the doctor to prescribe the best treatment.

030 Finally, it is equipped with pressing fins that its shape fits perfectly into the ambu bag, protecting it, unlike other artificial respirators in which the ambu bag is pressed in a punctual way, reducing the life of the piece, in addition to being an equipment physically robust, capable of facing environmental adversities, avoiding breaks during its operation that would represent the patient's respiratory arrest, leading to death. In case of breakages, it is easily and quickly repaired, without the need for a highly qualified professional, and is built with parts that are easily accessible on the market.

031 Because it is innovative and until then not understood in the state of the art, it fits perfectly into the criteria that define the patent of invention. Their claims are as follows.

Claims (2)

"IMPROVEMENT INTRODUCED IN HYBRID ARTIFICIAL RESPIRATOR WITH REMOTE CONTROL, WITH MONITORING SYSTEM, DATA STORAGE AND MISCELLANEOUS MEASUREMENTS" comprised of a respirator (1), formed from a casing (2) whose front section (3) describes a window ( 4), provided with cover (5) provided laterally with reliefs (6), characterized by internally housing a pumping device (7) formed by a sliding assembly (8), whose front face (9) in the lower section (10) holds a base (11), above which extends a cradle (12) that describes a concave conditioning base (13), which receives an ambu bag (14) that is pressed by a sliding vise plate (15), being the upper section (16) provided with bearing support (17), while the rear face (18) inferiorly projects a support (19) that houses a stepper motor (20), which receives the coupling of a threaded spindle (21) that it displaces. through a nut (22) the support plate (23) fixed to said sliding vise plate (15), the spindle (21) being superiorly fixed to the closing plate (24) of the bearing support (17), breather (1) is controlled by software that allows measuring the pressure, in addition to sensors to control the flow, oxygen and heart rate, through the control panel (25). "IMPROVEMENT INTRODUCED IN HYBRID ARTIFICIAL RESPIRATOR WITH REMOTE CONTROL, WITH MONITORING SYSTEM, DATA STORAGE AND MISCELLANEOUS MEASUREMENTS" characterized by the artificial respirator containing internal devices for measuring blood pressure, oxygenation, body temperature and heart rate.

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