DE4309923A1 - Apparatus arrangement for supplying respiration gas to a patient - Google Patents

Abstract

The invention relates to an apparatus arrangement (1) for supplying respiration gas to a patient, which comprises a nasal tube (4) or such like supply means which is connected via at least one respiration gas line to at least one source (3) of respiration gas, at least one regulating member being inserted in the respiration gas line. For adaptation of the amount of oxygen or respiration gas supplied by the apparatus arrangement (1) to the patient (2) to suit his/her current, individual respiration gas requirement, the apparatus arrangement (1) according to the invention comprises a blood gas saturation sensor (6) and a measurement and control unit (7) electrically connected thereto, the measurement and control unit (7) being in control connection with an electrically operated control member (8) for adaptation of the respiration gas volume to be supplied to the patient to the degree of blood gas saturation determined (cf. Fig. 1). <IMAGE>

Description

The invention relates to a device arrangement for feeding from breathing gas to a patient, with a nasogastric tube or the same feed device, which has at least one Breathing gas line connected to at least one breathing gas source is, with at least one control organ in the breathing gas line is interposed.

A person's arterial blood gas saturation level, ie the oxygen partial pressure (PaO ₂ ), is influenced, among other things, by the inspiratory oxygen content of the breathing gas and by the perfusion-related transport of oxygen to the tissue and its uptake in the mitochondria. Chronic diseases can cause this level of blood gas saturation, which is between 91 and 100% in healthy people, to drop permanently to lower values. A too low oxygen partial pressure can lead to a lack of oxygen in the tissue and irreversible tissue destruction. If the blood gas saturation level is too low, the blood vessels in the body narrow (so-called Euler-Liljestrand reflex), so that the patient's heart has to perform an additional life-reducing performance.

In order to raise a patient's level of blood gas saturation in such chronic diseases, it may be necessary to increase the inspiratory oxygen content of the breathing gas by means of an artificial supply of oxygen as part of long-term therapy. Steel pressure cylinders, O ₂ concentrators and liquid oxygen systems are available for such long-term therapy.

In recent years, the indication for supplying liquid oxygen has prevailed because it increases daily O ₂ inhalation, increases patient mobility compared to the location-dependent or network-dependent steel pressure cylinders and O ₂ concentrators, and, last but not least, ensures an improved quality of life of the patient.

The offered liquid oxygen systems exist consistently from a differently sized vacuum-insulated stainless steel Reservoir tank from 21 to 31 liters, in a stationary Base unit is included and liquefied cryogenic Holds oxygen as breathing gas. On this stationary Basic device can be a portable device unit (so-called "Strawler") fill up, the device tank has a capacity from 0.5 to 1.23 liters, which is what the patient with a usual flow rate of the oxygen flow to be supplied of 2 Liters / minute gives a mobility of 4 to 8 hours. In These devices become fluid and save space accordingly stored oxygen through a system of tubes, Heating coils and a flow control valve removed, too Evaporated gas, warmed to room temperature and on one different breathing gas volume adjustable flow regulator given to the patient. The patient wears one  possibly double-lumen nasal probe, a breathing mask, one intratracheal catheter or similar delivery device, which via a breathing gas line with the basic device or the portable device is connected.

The individual devices are each on the individual Adjust the patient's oxygen needs. For this the Arterial partial pressure of oxygen in the patient at rest measured and then the flow regulator of these devices set accordingly. With increased physical Stresses on the patient, but also during certain Sleep phases, this is artificially delivered to the patient Oxygen volume insufficient to desaturate the prevent oxygen contained in the blood. In such phases of activity or sleep, despite the however, insufficiently supplied breathing gas to the above described impairments and damage to the Patients come.

So-called demand systems have already been created, between the oxygen source and the patient attached feeder can be switched and it over allow an inspirationally triggered trick that Oxygen in a certain amount or in a certain Breathing cycle during the patient's inspiration phase to deliver.

With the help of these savings systems, inspiration-triggered demand systems can indeed Refill frequencies and thus the cost of the Liquid oxygen can be drastically reduced, however, too with the help of these devices a desaturation of the Oxygen content in the blood and possibly from it resulting impairments and damage to the Patients are not fully met.

There is therefore in particular the task of a To create a device arrangement of the type mentioned in the introduction, with such desaturation of the blood gas Saturation value also for example with loads or during certain phases of the patient's sleep can be counteracted.

The achievement of this task consists in the Device arrangement of the type mentioned in particular in that the device assembly detects a blood gas Saturation sensor and an electrically connected measuring and control device and that this measuring and Control device for adapting the patient to be supplied Breathing gas volume to the determined blood gas saturation level an electrically actuated control element in control connection stands.

The device according to the invention has a blood gas Saturation sensor with which the current arterial Partial oxygen pressure even during a patient Sleep phase or under special loads can. This blood gas saturation sensor is with one preferably electronic measuring and control device Device arrangement according to the invention electrically connected, which in turn with an electrically operated control element is in tax connection. To adjust the patient's pro Time unit of breathing gas volume to be supplied to the current determined blood gas saturation level is electrical actuatable control organ in the leading to a breathing gas source Breathing gas line interposed.

Since the device arrangement according to the invention Volume of oxygen delivered to patients per unit of time automatically at his current and individual breathing gas  Adjusting the need is constant monitoring of the patient also no longer necessary in clinics, which is also a can include significant cost savings. Furthermore increased therapy safety can be achieved because Deaths from oxygen supersaturation practically not there are more to fear. Because the patient essentially only the required amount of breathing gas is supplied, the works device according to the invention more cost-effective.

To a considerable physical relief of the patient also leads to hypersaturation occurring Euler-Liljestrand reflex effect and thus a Narrowing of the blood vessels is practically eliminated.

With the help of the device arrangement according to the invention possibly the patient's ability to work again be made because with help depending on the workload the device arrangement according to the invention each currently required amount of oxygen is supplied.

It is advantageous if the electrically actuatable control element as a proportional regulator, preferably as electromagnetic proportional valve is formed.

Such as blood gas saturation sensors, for example commercially available devices that serve the oxygen saturation in As part of an arterial blood circulation analysis or with the help of Measure transoxotes. However, one is preferred Embodiment in which the blood gas saturation sensor as Pulse oximeter is formed. Using such pulse oximeters, which determines the level of blood oxygen saturation by determining the Distraction of one placed on the patient's skin and in the red or ultraviolet light range emitting LED sensor blood gas saturation level in a bloodless manner be measured.  

Such a pulse oximeter is used during therapy with the Device arrangement according to the invention on the body of the To glue patients or to fasten the like. To that Patients the handling of the device according to the invention it is expedient if the blood gas Saturation sensor can be attached to a patient's finger and preferably as. Finger cot or finger clip trained or is designed as an adhesive sensor, which in particular at Children can be easily attached to the skin.

Basically, the device arrangement according to the invention can also be used with the help of conventional devices. An embodiment according to the invention provides that the device arrangement is a basic unit for feeding a specified or definable breathing gas volume and a Additional unit for feeding an additional one to one currently determined blood gas saturation level Has volume, the additional unit, the measuring and Control device is assigned, which with the blood gas Saturation sensor and the electrically actuated control element is in tax connection. In such an embodiment can, for example, a standard device as a basic unit serve while using the most compact possible to be designed additional unit to the patient additional, on the currently determined blood gas Adjusted degree of saturation gas volume is supplied.

A further development according to the invention of its own A device arrangement that is worthy of protection concerns to supply breathing gas to a patient, the one Has basic unit with a respiratory gas source, which over a main gas flow line with a nasal probe or the same feeder is connected, in which Breathing gas main line a mechanical blocking and / or Control element is interposed. For this continuing education  Embodiment according to the invention is characteristic that the Device arrangement an additional unit for feeding a additional to the current blood gas saturation level adjusted breathing gas volume, which is a blood gas Saturation sensor and an electrically connected measuring and control device is assigned that the additional unit via a breathing gas bypass line with the breathing gas source Basic unit is connected and that in to a nasogastric tube or similar supply device leading breathing gas Branch line an electrically operated and with the measuring and Control device in control connection is interposed.

In this further embodiment according to the invention can, for example, the required basic oxygen volume Patients are fed via the basic unit, the mechanical locking or regulating element of this basic unit preferably to that required by the patient at rest Breathing gas volume is designed or regulated. That from Patients with stress or in certain sleep phases in addition, he will need additional breathing gas volume supplied via the additional unit, which is correspondingly simple, can be designed to be compact and space-saving. Since the Additional unit only one individual and currently required subset of the required oxygen volume delivers, is u. a. also for the electrically operated The control unit of the additional unit is comparatively small Amount of electricity required. In particular a network independent and also for the power supply of warming up, measuring and Control device, etc. required power source Device arrangement according to the invention is thereby relieves what in turn the charging frequencies at this Device extends and patient mobility too so far favored.  

It is useful if the breathing gas main line and the Breathing gas bypass a common nasogastric tube or the same feeder is assigned and if the Breathing gas branch line with its downstream end area preferably opens into the main breathing gas line.

So that the doctor or the patient the total supplied to him It can estimate and record the amount of breathing gas advantageous if a flow meter is used in the breathing gas line Display of the supplied breathing gas volume is interposed and if the flowmeter is in the flow direction of the mouth between breathing gas main and bypass preferably is connected downstream.

In order to also check the proper functioning of the device arrangement according to the invention and to be able to detect sufficient blood gas saturation in the patient's blood count, it is advantageous if the device arrangement, in particular its additional unit, is used - in addition to or instead of the flow meter - to display the amount of blood gas Saturation sensor determined current blood gas saturation degree has a display electrically connected to the measuring and control device, a screen, a printer or the like data output device. A particularly advantageous and versatile embodiment according to the invention provides that the basic unit and / or the additional unit is designed as a portable and preferably separable device and that the basic unit and / or the additional unit have a common, mains-independent power source. A battery or accumulator block required for the heating coils or the like of the basic unit can also serve as the current source, to which the additional unit, which is also designed to save electricity, is electrically connected. It is also possible to use such a portable, separate additional unit in the context of a liquid oxygen system both with the usual basic device and with the associated portable device. Such a separate additional device can also be used advantageously in connection with oxygen bottles or with O ₂ concentrators, for example in the clinic area.

In the latter cases in particular, it can however, be useful if the device arrangement, in particular, their additional device does not have just one off-grid power source, but also has a Power supply unit can be connected to the mains.

Despite the versatile application possibilities of Device arrangement according to the invention is based on the reasons mentioned preferred an embodiment in which the Breathing gas source is designed as a liquid oxygen container. The additional unit can have its own Have liquid oxygen tanks. However, this Additional unit as compact and space-saving as possible To design, it is useful, if also the additional unit as the breathing gas source of the liquid oxygen container Basic unit is assigned.

Further features of the invention result from the following Description of an embodiment according to the invention in Connection with the claims and the drawing. The individual characteristics can be used individually or in groups an embodiment according to the invention.

Fig. 1 shows a device arrangement for supply of breathing gas to a patient in a block diagram, the apparatus arrangement has a base unit and an associated auxiliary unit of an additional, adapted for feeding to a currently determined blood gas saturation has respiratory gas volume, and

Fig. 2 is a perspective view of the device arrangement consisting of the basic device and the additional device during use on a patient.

Figs. 1 and 2 show an apparatus arrangement 1 for the supply of respiratory gas to a patient 2. The device arrangement 1 has a liquid oxygen container 3 , which is connected as a breathing gas source via a breathing gas line to a double-lumen nasal probe 4 . Instead of the nasal probe 4 , a breathing mask or similar supply device can also be provided. If the patient's oxygen demand is particularly high, a transstrachial catheter, for example, is suitable as a supply device.

A mechanical control valve or similar control element 5 is interposed in the breathing gas line and is regulated to the volume of oxygen to be supplied by the patient in the rest position.

As Fig. 1 shows, the device assembly 1 is a blood gas saturation sensor 6 which is connected to a measuring and control device 7. This electronic measuring and control device is in control connection with an electrically actuatable control element 8 , which is connected in a by-pass of the breathing gas line, to adapt the breathing gas volume to be supplied to the patient to the breathing gas volume determined by the blood gas saturation sensor 6 .

For this purpose, the breathing gas line is subdivided into a main breathing gas line 9 and a secondary breathing gas line 10 . Here, the inflow-side end of the branch line 10 is connected in the flow direction before the mechanical Flußmengenregler 5 with the breathing gas line and opens in the direction of flow for this control member 5 turn in the respiratory gas main. 9 In the breathing gas secondary line 10 , the electrically actuatable control element 8 is provided, which is preferably designed as an electromagnetic proportional valve.

The liquid oxygen tank 3 and the mechanical control valve 5 belong to a basic unit, the housing of which is indicated in FIG. 1 by a dashed line 11 . The electromagnetic proportional valve 8 and the measuring and control device 7 in control connection with it are part of an additional unit 12 , which is also associated with the blood gas saturation sensor 6 . The blood gas saturation sensor is designed here as a finger cot or finger clip which, as a pulse oximeter, measures the level of blood gas saturation in a bloodless manner by deflecting the light rays emanating from an LED sensor. The blood gas saturation sensor 6 , which is designed as a finger clip, can be easily attached to a finger of the patient.

The liquid oxygen stored in the liquid oxygen container 3 is first evaporated to gas via a system of pipes and heating coils and then warmed to room temperature. This warmed oxygen gas flows into the main and secondary breathing gas lines 9 , 10 . While the patient is fed to a matched to the oxygen demand in the rest position by means of the mechanical Flußmengenregler 5 breathing gas base volume via the main line 9, 10 is released, if required, additional volume of oxygen on the secondary line, which is also required for stress of the patient or in particular sleep stages of this . For this purpose, the patient's current blood gas saturation level is continuously determined via the blood gas saturation sensor 6 . If this level of blood gas saturation or the arterial oxygen partial pressure drops to values that require an additional supply of oxygen, the measuring and control device 7 connected to the blood gas saturation sensor 6 opens the electromagnetic proportional valve 8 to the required extent.

In order to be able to estimate and measure the total volume of the oxygen supplied to the patient, it is expedient if a flow meter 13 shown in FIG. 2 is interposed in the breathing gas line. This flow meter 13 can be provided in the flow direction upstream of the connection point between the main and secondary breathing gas lines 9 , 10 , but is expedient if the flow meter 13 is connected downstream and in the direction of flow of the mouth between the main and secondary breathing gas lines 9 , 10 is integrated in the additional unit 12 .

To display the blood gas saturation level ascertained by the blood gas saturation sensor 6 , a display or similar data output device can also be provided on the additional unit 12 , for example, which also offers the patient the possibility of ensuring that the device arrangement 1 is operating correctly and is adequately supplied with oxygen .

The device arrangement 1 can also be designed as a single device, in whose breathing gas line only the proportional valve 8 connected to the measuring and control device 7 is interposed. However, the embodiment shown here, which has the separable basic and additional units 11 , 12 , is preferred. This embodiment makes it possible not only to use the same additional unit in conjunction with other customary oxygen sources, such as, for example, oxygen cylinders or O ₂ concentrators, but rather to use the additional unit 12 in conjunction with conventional liquid oxygen systems, which consist of a stationary base unit and a portable unit consist. In FIG. 2, for example, the portable device of a liquid oxygen system forms the basic unit 11 , while the additional unit 12 , which is also designed as a portable device, is detachably coupled therein.

In order to be able to use the additional unit 12 both with the stationary base unit and with the portable unit of a liquid oxygen system, the auxiliary unit 12 is assigned a mains-independent power source, which is integrated, for example, into the additional unit 12 . However, the batteries of the base unit 11 to which the additional unit 12 is to be connected can also serve as the mains-independent power source.

In addition, the additional unit 12 can also be connected to the power supply via a power supply unit that is not visible here, so that the additional unit 12 can also be used with a stationary device and used, for example, at night or in the hospital.

In the device arrangement 1 described here, the amount of oxygen supplied to the patient is adapted to the patient's current individual breathing gas requirement. This can lead to a considerable physical relief for the patient, because the Euler-Liljestrand reflex effect, which occurs in the event of undersaturation of oxygen, is practically eliminated. Since essentially only the required amount of breathing gas is supplied to the patient and constant monitoring of the patient, for example in the clinic area, is no longer absolutely necessary, the device according to the invention operates cost-effectively.

Claims (12)

1. Device arrangement for supplying breathing gas to a patient, with a nasogastric tube or similar supply device which is connected to at least one breathing gas source via at least one breathing gas line, at least one control element being interposed in the breathing gas line, characterized in that the device arrangement ( 1 ) has a blood gas saturation sensor ( 6 ) and a measuring and control device ( 7 ) electrically connected to it, and that this measuring and control device for adapting the volume of breathing gas to be supplied to the patient ( 2 ) to the determined blood gas saturation level with an electrically actuated control element ( 8 ) is in control connection. 2. Device arrangement according to claim 1, characterized in that the electrically actuatable control element ( 8 ) is designed as a proportional control element, preferably as an electromagnetic proportional valve. 3. Device arrangement according to claim 1 or 2, characterized in that the blood gas saturation sensor ( 6 ) is designed as a pulse oximeter. 4. Device arrangement according to one of claims 1 to 3, characterized in that the blood gas saturation sensor attachable to a finger of the patient and preferably trained as a finger cot or finger clip or as Adhesive sensor is designed. 5. Device arrangement according to one of claims 1 to 4, characterized in that the device arrangement comprises a basic unit ( 11 ) for supplying a fixed or definable breathing gas volume and an additional unit ( 12 ) for supplying an additional, adapted to a currently determined level of blood gas saturation Breathing gas volume, the additional unit ( 12 ) being associated with the measuring and control device ( 7 ), which is in control connection with the blood gas saturation sensor ( 6 ) and the electrically actuatable control element ( 8 ). 6.Device arrangement for supplying respiratory gas to a patient, which has a basic unit with a respiratory gas source, which is connected via a main respiratory gas line to a nasal probe or similar supply device, a mechanical blocking and / or regulating element being interposed in the main respiratory gas line. In particular according to one of claims 1 to 5, characterized in that the device arrangement ( 1 ) has an additional unit ( 12 ) for supplying an additional breathing gas volume adapted to the current blood gas saturation level, which has a blood gas saturation sensor ( 6 ) and a it is associated with the electrically connected measuring and control device ( 7 ) that the additional unit ( 12 ) is connected to the breathing gas source ( 3 ) of the basic unit ( 11 ) via a breathing gas branch line ( 10 ) and that into a nasal probe ( 4 ) or similar supply device leading breathing gas secondary line ( 10 ) an electrically operated and with the measuring and control device ( 7 ) in control connection with a control element ( 8 ) is interposed. 7. Device arrangement according to one of claims 1 to 6, characterized in that the breathing gas main line ( 9 ) and the breathing gas secondary line ( 10 ) is assigned a common nasogastric tube ( 4 ) or the like supply device and that the breathing gas secondary line ( 10 ) with its downstream end area preferably opens into the main breathing gas line ( 9 ). 8. Device arrangement according to one of claims 1 to 7, characterized in that a flow meter ( 13 ) for displaying the supplied breathing gas volume is interposed in the breathing gas line and that the flow meter in the flow direction of the mouth between breathing gas main and secondary line ( 9 , 10 ) is preferably connected downstream. 9. Device arrangement according to one of claims 1 to 8, characterized in that the device arrangement ( 1 ), in particular its additional unit ( 12 ), for displaying the current blood gas saturation level ( 6 ) determined by the blood gas saturation sensor (a) with the measuring and control device ( 7 ) has an electrically connected display, a screen, a printer or the like data output device. 10. Device arrangement according to one of claims 1 to 9, characterized in that the basic unit ( 11 ) and / or the additional unit ( 12 ) is designed as a portable and preferably separable device and that the basic unit ( 11 ) and / or the additional unit ( 12 ) have, in particular, a common network-independent power source. 11. Device arrangement according to one of claims 1 to 10, characterized in that the device arrangement ( 1 ), in particular its additional unit ( 12 ), can be connected to the mains via a power supply unit. 12. Device arrangement according to one of claims 1 to 11, characterized in that the breathing gas source is designed as a liquid oxygen container ( 3 ).