DE102008039645A1 - Medical technical component, particularly resuscitation mask, is provided with textile material, where textile material has two surfaces - Google Patents

Abstract

The medical technical component is provided with a textile material (4), where the textile material has two surfaces. The former surface is intended for application against a skin of a user. An increased gas pressure is applied on the former surface. An intermediate layer is provided between the two surfaces.

Description

The The invention relates to a medical component.

in the The field of medical technology is becoming predominant Plastic used. The advantage is a simple and cheap Production of the parts. Also the light weight of a plastic part is advantageous.

Just but where medical devices have patient contact, Plastic is not always well suited. Medical respiratory masks off Plastic does not provide a comfortable fit for the patient and can Skin reddening due to continuous contact with the skin of the patient rashes or cause other allergic reactions. Unpleasant is also the sweating while wearing such a mask.

Under In the following, textile materials are generally all fiber-based Materials understood. These are on the one hand textile materials in the true sense, about it but also flow-like materials or materials of pressed fibers. The term fiber here includes natural and synthetic fibers, for example cotton or cotton fibers Wool, paper fibers, fibers made of plastics or of a combination different materials.

task It is the object of the present invention to provide a component of the preamble mentioned type to improve such that an improved comfort achieved becomes.

These Task is inventively characterized solved, that in an area intended to rest on a skin of a wearer Component arranged at least partially a textile material is.

The inventive idea describes the use of textile materials for medical components. Textile materials belong Today, the most important high-tech materials. Have textile materials Features and functions that are for example pleasant affect the feel. Textile materials find their way into the patient higher acceptance and have a much better image than plastics. Textile Materials are comfortable to wear and very easy to clean, what you get from other field of use of textile materials knows. The attachment of a respiratory mask, such as harnesses and hoods, is already made of textile materials.

A Application is possible for a intelligent textile patient interface for use in the continuous positive-pressure ventilation therapy (CPAP - Continuous Positive Airway Pressure) and in the care of emergency and intensive care patients. The patient interface consists of a mask for the pressure supply and a Hood for the ensures proper fit of the mask and serves as a sensor / actuator carrier. As materials Thermoplastic, elastomeric and textile materials are used. The use of sensors records the course of sleep as well as the mask seat and the print settings optimized. By a simplified derivation of physiological parameters from the detected sensor signals is the effectiveness of the automatic Setting regulated and improved. This will be a significant higher compliance achieved this therapy and with the patient interface as a textile Product expected significant competitive advantages.

• • Textil besitzt positives Image, dadurch werden dem Patienten natürliche Ängste genommen.
• • Der Umgang mit Textilien ist den Patienten vertraut. So können textile Maskenteile einfach in der Waschmaschine gewaschen werden und müssen nicht aufwändig gereinigt werden.
• • Durch den Einsatz intelligenter Textilien ist es möglich eine Maske zu schaffen, die ihre Passform individuell an die Passform des Gesichts anpasst. Hierdurch wird die Anwendung der Maske auch bei Patienten mit anatomischen Eigenheiten, wie z. B. Gesichtsdeformationen, möglich.
• • Intelligente Textilien im Bereich des Ausatemsystems ermöglichen eine therapiedruckunabhängige Auswaschung der ausgeatmeten CO2-haltigen Luft.
• • Es wird eine Maske bereitgestellt, die durch Einsatz textiler Materialien den Tragekomfort deutlich erhöht und optimiert.
• • Es wird eine textile Haube mit integrierter Sensorik bereitgestellt, um physiologische und zustandsabhängige Parameter kontinuierlich zu erfassen.
• • Es wird eine Signalerfassung und automatische Regelung zur optimalen Einstellung und Anpassung der Therapie- und Zustandswerte bereitgestellt.

The use of textile material has the following advantages:

• • Textile has a positive image, which causes the patient natural fears.
• • The handling of textiles is familiar to the patient. So textile mask parts can be easily washed in the washing machine and do not need to be laboriously cleaned.
• • By using intelligent textiles, it is possible to create a mask that adapts its fit individually to the fit of the face. As a result, the application of the mask is also in patients with anatomical features such. As facial deformations possible.
• • Intelligent textiles in the area of the exhalation system enable a therapy pressure-independent leaching of the exhaled CO2-containing air.
• • A mask is provided that significantly increases and optimizes wearing comfort through the use of textile materials.
• • A textile hood with integrated sensors is provided to continuously record physiological and condition-dependent parameters.
• • Signal acquisition and automatic control are provided for optimal adjustment and adjustment of therapy and condition values.

The sensors in the hood and mask record the physiological and condition-dependent parameters of the patient. Thus, the sleep profile (wake, REM and non-REM sleep) is derived by EEG electrodes in the hood in order to regulate the therapy device depending on the sleep stage and additionally to document the efficiency of the therapy. A sound sensor in the mask detects the breath sounds and provides information about the patency of the pharynx. This information is used for the individual regulation of the therapy pressure to the necessary minimum. A CO2 sensor In the mask, the active control of the leaching of exhaled CO2-containing air is used.

• • Die intelligenten Textilien passen ihre Form individuell an die Gestalt des Gesichts an.
• • Die Durchlässigkeit der Textilien ändert sich in Abhängigkeit vom Therapiedruck und der Gradientenstruktur im textilen Aufbau der Maske.
• • EEG-, Schall- und CO2-Sensoren, die in die textile Haltevorrichtung eingearbeitet sind, ermöglichen eine individuell angepasste Regelung der Beatmung.

The technical features and challenges are given by the following features:

• • The intelligent textiles adapt their shape individually to the shape of the face.
• • The permeability of the textiles changes depending on the therapy pressure and the gradient structure in the textile structure of the mask.
• • EEG, sound and CO2 sensors, which are incorporated in the textile holding device, allow for individually adjusted ventilation control.

The pleasant and skin-friendly properties of a textile be integrated into a mask bulge, as this also on the skin of the Patient is present. At the same time, the properties of Textiles like breathability, Dissipate the moisture from the skin inwards and permeability be used. It can but also other parts of a respiratory mask, such as the Mask body the forehead support or even an exhalation system made of textile materials become.

Of the textile material can be at least partially made of natural fibers, which of animal, vegetable or mineral origin, and / or Be made art or chemical fibers or partially a functional fabric made of cotton and polyester. Specific Fibers are used, the moisture quickly away from the skin transport and so a cooling on the skin. In the fibers but also agents such as Skin creams, aloe vera etc are introduced.

Textile Materials can be shaped just like plastics, for example by molding (molding process by heat and pressure), but have z. B. skin-friendly properties. By molding For example, the shape of the mask bulge or nasal pillows is pronounced here The shape of the bead or the nasalpillows becomes from a laminate impressed. The laminate can consist of several identical or different layers Textile are each made with special properties such as: skin-friendly, breathable, airtight.

In If necessary, the molded textile can be given a stiffening body be, for example, a Abstandgewirk, due to its large mesh size be flowed through very well by water can and does not affect the cleaning despite its thickness. By welding certain areas the side walls be specifically stiffened the bead.

Textile Materials can but also used as a coating on other materials or connected to other materials. So can the mask bead be knotted from textile material on a mask body. That's right the interface to the mask body a ring of z. As silicone or TPE attached. But the materials can be permanently connected.

The Textile materials offer the possibility of being light and simultaneous To realize highly resilient structures and thus form an attractive Alternative to conventional Respiratory masks. They are easy to clean, they can even be washed in the washing machine.

One another very important aspect for the use of a textile material for respiratory masks is the property the air permeability of the material. The production of a mask body made of a textile fabric allows it, the mask body to use as an exhalation system. Typically, the pressure is at inhalation higher. The higher the therapy pressure is the lower it is due to the following Material compression the permeability the textiles of the invention. hereby is a substantially constant flow through the textile material allows through. In particular, it is thought that at an applied pressure constant breathing gas over the textile flows out. Textiles that are compressed depending on therapy pressure become possible an exhalation system with a straight curve. This is opposite one usual Exhalation system much quieter, because over the entire material surface finest pores to be provided. This is the per air pore exiting air volume very low, which allows a diffuse distribution of exhaled air.

Textile surfaces are a composite of fibers or yarns non-woven (such as Felt) or thread systems by weaving, knitting, or knitting other joining fibers are formed.

The Patient interface consists of a textile pressure and breath-sensitive Mask with integrated sensors. The use of textile material converts the wearing characteristics: the mask becomes a clothing. By the stratification of textile material with different flow and pressure-dependent Properties as well as through the use of integrated sensors Is it possible, the sufficient therapy pressure as a function of the physiological Condition of the patient during The inhalation and expiratory phase automatically regulated to keep minimal.

Crucial for the patient is above all the comfort of wear, as the surfaces of the mask on the skin of the patient. The textile surface structure adapts optimally to the individual facial physiognomy of the patient. Noise emission is minimized by the use of Mul tiplex textiles, which change their permeability depending on the pressure. Sensors record the function parameters of the interface. They monitor the sleep profile as well as the respiration of the patient. From the status signals, parameters for optimal regulation of the therapy pressure are determined.

In The drawings are exemplary embodiments of the invention shown schematically. Show it:

1 FIG. 2: a partially perspective and sectional view of a part of a respiratory mask with a textile cover layer in regions, FIG.

2 one opposite 1 modified embodiment with reinforcing ribs,

3 a further modified structure with a cross-type reinforcing structure,

4 a longitudinal section through a compressible material in an unloaded state,

5 the material according to 4 in a pressurized state,

6 a longitudinal section through another material with flow channels in a ground state and

7 the material according to 6 in a pressure-loaded state.

1 puts a mask bead ( 1 ) in section, in which indoors ( 2 ) a full-surface stiffening ( 3 ) made of plastic and in the outer area a textile material ( 4 ) is arranged. The area ( 5 ) for attachment to the mask body is also made of plastic, such as silicone, which is molded.

2 also shows a sectional view of a mask bead ( 1 ), in which stiffening ribs ( 5 ), for example made of silicone, are back-injected and the interface area ( 5 ) is also sprayed to the mask body. A transition ( 6 ) is gentle.

3 shows a cross-ribbing ( 7 ) indoor ( 2 ) of a mask bead

In the 4 and 5 the material structure with different materials is displayed once and once loaded. The load pressure is indicated by arrows. The materials may have a different porosity or permeability. The intermediate layer changes its layer thickness and / or its permeability dependent on pressure. Textiles that are compressed depending on the therapy pressure allow an exhalation system with a straight curve.

Functional fibers according to the invention or functional parts of the textiles of the invention are in the tissue woven and / or embroidered and / or laminated from several layers and or printed on the fabric.

The fabrics of the invention are preferably washable several times without significant structural and / or Loss of function.

Also in the 6 and 7 a material structure with different materials is displayed once and once loaded.

The in the 4 to 7 illustrated materials allow the provision of pressure-controlled flow resistance. In particular, it is possible to provide an increased flow resistance with increasing pressure by the material compression. When used in the area of respiratory masks, this makes it possible to minimize leakage in an active ventilation pressure and to allow a flow of the material to exhale at a low pressure in the expiratory phases.

It is also possible, for example, according to a modification of the embodiments in 6 and 7 To provide a reduced flow resistance by a pressure-dependent expansion of the discharge channels with increasing pressure. The material according to the invention thus makes it possible, if appropriate by means of a combination of compressive materials and expandable flow paths, to increase both increasing and decreasing flow resistance with increasing pressure. It is also possible to provide a pressure-independent constant flow resistance by means of a suitable material construction.

At the explained below embodiment is the application of the materials of the invention by way of example a patient interface, in particular using the example of a respiratory mask explained in more detail.

The patient interface is made of the combination of textile materials of different pressure and flow properties in the form of a multiplex layering with integrated electrically conductive Built up fibers. Sensors and actuators are integrated into the textile support layers and connected to the control electronics of the compressor by means of the electrically conductive fibers. The patient interface consists of the mask and the hood, both made of a combination of textile materials. An optimal fit with the pleasant, skin-friendly properties of the textiles is achieved. At the connection points with the surfaces resting against the skin and the hose connections and adapters necessary for the supply, a material composite of textile and plastic or silicone is used.

The Mask must have sufficient structural stability and very much at the same time be skin- and tissue-friendly without losing its sealing effect. To is the previously formed from silicone mask of textile structures, such as thermobondable needled nonwovens made of polyester-melt adhesive fiber blends or meltblow nonwovens made of elastic thermoplastics. The nonwovens will be while 3-dimensional reshaped and fixed.

Of the Structure as textile gradient materials, eg. B. with different Adhesive fiber proportions and wall thicknesses, allows to set the stiffness of the structure. The Dense lips to the skin become a soft textile feel with high body compatibility own, stiffer and stable walls at the same time preserve the shape of the mask and ensure an individual Fit. By the specific choice of mesh or pore size is the flow resistance targeted and supported so active the pressure control. For the masks are suitable for textile use Care, z. B. in the washing machine to clean.

A Hood combines the optimal fit of the mask with high comfort. At the same time she is carrier the sensors as well as the data lines and the power supply. The optimal fit will be, inter alia, through the fully fashioned knit technology, d. H. shapely and without disturbing cut edges and seams, produced. Here is the force-strain behavior of the textile structure decisively for the secure fit.

It For example, 3 EEG sensors including the associated signal processing modules integrated into the textile hood. The electrical connection is through integrated conductive Textile fibers reached.

The flow in the mask and on the exhaust valve as well as leaks can through measuring a flow or sound sensor into the mask. The Signal from the flow sensor provides the information about inhalation and expiration of the Respiratory phase. From the waveform, the pressure increase and lowering for optimal care of the patient.

In The mask is integrated with a sensor that measures the CO2 concentration of the inhaled and inhaled air and this for the active control of leaching the exhaled CO2-containing air supplies.

The Signals are processed close to the sensor. The energy supply of Sensors as well as the transmission the signals from the hood to the evaluation and control unit takes place with elastic, electrically conductive yarns that over one too Adapters are connected to leads from the mask over the Route the hose to the control unit of the system.

Claims (15)

Medical component consisting at least partly of textile materials, characterized in that the textile material has a first surface and a second surface, and that the first surface is intended to rest against a skin of a user. Medical component according to claim 1, characterized characterized in that on the first surface at least temporarily a increased gas pressure is applied. Medical component according to claim 1 or 2, characterized in that the textile material between the first surface and the second surface has at least one intermediate layer. Medical component according to one of claims 1 to 3, characterized in that the first surface and the second surface and Intermediate layer have different textile structures. Medical component according to one of claims 1 to 4, characterized in that the textile material at least partly in addition is coated. Medical component according to one of claims 1 to 5, characterized in that the textile material at least partly additional electrically conductive Shares. Medical component according to one of claims 1 to 6, characterized in that the textile material at least permeable in one direction for water vapor is. Medical component after a of claims 1 to 7, characterized in that the textile material is permeable to gases at least in one direction. Medical component according to one of claims 1 to 8, characterized in that the textile material at least permeable in one direction for gases is and the permeability of dependent gas pressure dependent is. Medical component according to one of claims 1 to 9, characterized in that the textile material at least partially is a functional tissue which is compressible depending on pressure is. Medical component according to one of claims 1 to 10, characterized in that the textile material on the Patients facing side has a soft feel. Medical component according to one of claims 1 to 11, characterized in that the textile material at least partially a functional fabric of cotton and polyester is which Provides protection against moisture, pollution and grease. Medical component according to one of claims 1 to 12, characterized in that the Material at least one substance from the group polyester, polylactate, Polypropylene, polyethylene, polyacrylic, polyamide contains. Medical component according to claim 13, characterized characterized in that Material contains a combination of at least two fibers, the each made of a different material. Medical component according to one of claims 1 to 14, characterized in that the Intermediate layer is formed of a foam-like material.