RU78653U1 - DEVICE FOR SIZING SOFT-WOVEN STRUCTURES - Google Patents

Abstract

A device for determining the dimensions of soft-tissue structures, including a measuring device, characterized in that it comprises a housing on which a stationary stand with an electric probe is placed perpendicular to it, a movable stand with an electric probe with the possibility of dosed movement along the housing; the base of the movable stand is connected with the pointer arrow; between the racks on the surface of the housing there is a measuring scale with the origin from the projection of the end of the electric probe placed on a stationary rack on the surface of the housing; electrical probes are connected to an electrical measuring device, for example an ohmmeter, through an audio and / or light signal.

Description

The utility model relates to the field of medicine, in particular to the field of diagnostics and measuring instruments for studying the configuration, size or movements of the human body, and can be used to determine the size of soft tissue structures.

It is known to use a micrometer for measuring soft tissue structures. The micrometry method has found extremely wide application in technology. In morphological studies and in medicine, the method is not so widely used. According to our data, in Russia the micrometer was not previously used to evaluate the metric parameters of soft tissue structures of the maxillofacial region. The pressure exerted by the cheeks of the micrometer (S cheeks = 0.3 cm ² ), for common models = 7-10 N, for the most advanced samples 0.8-1.0 N, therefore, the pressure on the tissues will be (maximum) 0.3 * 10 / 9.8 = 0.306 kg / cm ² when using common models, or (minimum) 0.3 * 0.8 / 9.8 = 0.024 kg / cm ² when using more modern equipment. An important feature of the micrometer is the independence of pressure on the measurement object from the actions of the researcher (the pressure is constant for each type of device and does not depend on the applied effort of the researcher in the measurement process), as well as the ability to calibrate the device with great accuracy. Literature data suggest that such pressure values should not lead to irreversible changes in connective tissue structures, with a thickness of structures comparable to the thickness of the capsule of the temporomandibular joint (0.4-1.7 mm) or greater. Our practice of carrying out such measurements on sectional material, including repeated control over the same parameters fixed by standard formalin methods, showed that the method does not lead to visually pronounced changes in the studied tissues. The only negative point that does not allow us to talk about the complete reversibility of changes in the tissues is associated with injuries arising from the sharp edges of the moving cheek of the micrometer, which are present from the moment the cheeks come into contact with soft tissues until the above pressure is reached.

The disadvantage of using a micrometer for measuring the size of soft tissue formations is the low accuracy of the study.

The purpose of the utility model is to provide improved measurement accuracy of soft tissue biological structures.

The goal is achieved in that the device for determining the dimensions of soft tissue structures, including a measuring device, comprises a housing on which a stationary stand with an electric probe is placed perpendicular to it, a movable stand with an electric probe with the possibility of dosed movement along the case; the base of the movable stand is connected with the pointer arrow; between the racks on the surface of the housing there is a measuring scale with the origin from the projection of the end of the electric probe placed on a stationary rack on the surface of the housing; electrical probes are connected to an electrical measuring device, for example an ohmmeter, through an audio and / or light signal.

Figure 1 presents a General view of the device.

A device for determining the dimensions of soft-tissue structures, including a measuring device, comprises a housing (1) on which a stationary stand (2) with an electric probe (3) is placed perpendicular to it, a movable stand (4) with an electric probe (5) with the possibility of metered movement along enclosures (1); the base of the movable stand (4) is connected with the pointer arrow (6); between the racks on the surface of the housing there is a measuring scale (7) with a count from the projection of the end of the electric probe (3) placed on a stationary rack (2) on the measuring scale (7); electrical probes (3, 5) are connected to an electric measuring device (8), for example, an ohmmeter, through a source of sound (9) and / or light signals (10).

The device operates as follows.

The test object is placed on the housing (1) between the stationary (2) and movable (4) racks so that it is in contact with the electric probe (3) placed on the stationary rack (2). The movable stand (4) is moved until the contact of the electric probe (5) placed on it is reached with the measured biological object. A biological object, being a conductor of electric current, closes the electric network between the electric probes (3, 5); the panel of the electric measuring (8) device shows the presence of an electric current in the network, at the same time, sound (9) and / or light (10) signaling sources are turned on. Sizes of the investigated

the object is identified on the measuring scale (7), taking into account the number on which the pointer arrow (6) is fixed.

One of the problems of conducting quantitative measurements of the metric parameters of soft-tissue structures is the possibility of their deformation when taking readings. In this regard, when using the meter, crown meter and caliper, the obtained data will depend on the force of tissue compression during the measurement. This circumstance not only makes it difficult to repeat the measurement data by another researcher, but also affects the reproducibility of the results, which significantly reduces the scientific value of the latter. The data obtained largely depend on the pressure exerted directly by the researcher.

It should be noted that the above methods can be successfully applied in the evaluation of bone structures (as well as structures of hard tissues of the tooth). At present, they are also widely used to evaluate soft-tissue structures, but in this case one has to put up with a possible error, which, according to our data, reaches up to 15-20% of the measured value, take it into account in further statistical processing of the data, which leads to the need to increase the sample and, ultimately, increases the time of the study, increases its cost, or leads to a decrease in its evidentiary value.

Improving the measurement accuracy when using the proposed device is achieved by eliminating the deformation of the investigated tissue that occurs when working with known measuring instruments.

Claims (1)

A device for determining the dimensions of soft-tissue structures, including a measuring device, characterized in that it comprises a housing on which a stationary stand with an electric probe is placed perpendicular to it, a movable stand with an electric probe with the possibility of dosed movement along the housing; the base of the movable stand is connected with the pointer arrow; between the racks on the surface of the housing there is a measuring scale with the origin from the projection of the end of the electric probe placed on a stationary rack on the surface of the housing; electrical probes are connected to an electrical measuring device, for example an ohmmeter, through an audio and / or light signal.