DE1980315U - PROBE FOR MEASURING THE VOLUME OF BLOOD INFLOW IN THE VESSEL AREAS. - Google Patents

Description

Dr. Jürgen Gutmann
Gerlinde Gutmann

Sensor for measuring the volume of blood flowing into the vascular area

The measurement of the amount of blood flowing into a limb section per unit of time is a diagnostic aid Occlusive diseases and circulatory disorders. A very old method of performing this measurement is vein occlusion plethysmography With this method, the venous drainage in the limb section to be examined is blocked and the increase the volume measured as a result of the arterial inflow of the blood. Various methods are used to measure the increase in volume. In water plethysmography, the appropriate limb section is identified embedded in a rigid shell filled with water and determines the water displacement. Air plethysmography is analogous to this handled. A third option is to measure the circumference and the lymph in gs would increase.

1 ° A8 described by WHITNEY a method that uses an elastic rubber hose that is filled with mercury, and around the examining extremity is placed. The electrical resistance of the trapped mercury changes proportionally to its length and thus with the circumference of the extremity.

The method used so far had three main shortcomings. Of the The specific resistance of mercury is temperature-dependent. When applying a tube to an extremity with a body temperature of 37 degrees, an undefined temperature is set in the mercury, which lies between body temperature and air temperature. This relatively slow setting creates a drift during the measurement. The second disadvantage is the friction between Tube and skin. Various authors therefore recommended measures such as B. powder in order to be able to take a measurement at all. The third The disadvantage is that the hose cuts into the tissue.

The invention relates to a sensor for measuring the increase in circumference on limbs and thus the increase in volume with venous blockage,

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which avoids the disadvantages described. The idea behind the invention ^{: ί #} is to avoid friction between the skin and the hose and to provide thermal insulation between the limbs and the hose and to enlarge the contact surface. The invention is to be explained using an exemplary embodiment which is shown in FIG. The elastic hose (1) forms a loop so that the measuring distance is doubled. It is pulled through sliders (2), which are made of a material that has a low thermal conductivity and enables the least possible friction between the hose and the slider. The end pieces (3) and (4) are used for electrical connection, locking and calibration.

There are various ways of converting the measured increase in resistance into volume values or into the amount of blood flowing in / 100 ml of tissue. For example, a calibration value can be determined by stretching the hose by a known amount or the calculation can be carried out directly from the measured resistance values. The first possibility is realized by a device in the end piece 4 (Fig. 1), which is shown separately in Fig. 2. In it is (6) the end block and (7) an angle to which the fastener chain (8) or fastener tape is attached. In the tensioned state, the angle is in the position shown. If the handles (9) and (10) are pressed together, the hose is stretched by the known length AL. In the embodiment example Fig. 2, the angle takes over the parallel guidance, which is intended to prevent tilting. However, this can also be achieved by other measures, as Fig. 3 shows.

A calculation of the amount of blood flowing in per 100 ml of tissue is off the measured electrical "values are possible directly. It can be shown that the formula

V ü. E.

where ^ V is the increase in volume, V is the volume of tissue, ATJ is the increase in size and U is the size of the tissue section and AR or R is the increase in resistance or the electrical resistance of the sensor.

Since in practice the electrically active length of the mercury column does not exactly correspond to the circumference, the result determined in this way must be corrected depending on the length of the electrically inactive intermediate piece - in the example given, the chain. It is therefore sensible to identify the correction factor on the fastener tape (13) or fastener chain (8). This can be done by printing or coloring appropriate sections. Appropriately, the hole or link spacing is chosen so that simple correction values such as z. B. result in 1 % per gap.

Since the handling of mercury in clinics always poses a certain risk, appropriate measures must be taken to ensure that the hoses are unlikely to tear off. This can be done primarily through overstretching protection. For this purpose, the sliders (2) contain additional bores through which one or more inextensible ropes are pulled, which are longer than the mercury hoses by the allowable degree of expansion. Another embodiment of an overstretch protection is shown in Fig. 6 . Here, inserted bars take over the end limitation.

Another way to eliminate the dangers of mercury, is based on replacing the mercury hoses with inextensible ropes and a capacitive inductive one at one point on the sensor or to attach resistive transducers.

Claims (6)

RA.018 425 * 11.1.68 PROTECTIVE CLAMP 1. Sensor for measuring the increase in circumference of tissue sections, the is characterized in that the part (1) used for the Uraf angsme ssung is separated from the skin by sliders (2). 2. Sensor according to 1, which is characterized in that the measuring part (l) elastic and filled with mercury. 3- measuring sensor according to 1, which is characterized in that the measuring part (l) is inextensible, and the change in length by one on the probe attached inductive, capacitive or resistive transducer is measured. k. Measuring sensor according to 2, which is characterized in that an inextensible rope (5) or the like is drawn in to avoid overstretching of the hoses. 5 · measuring sensor according to 1, which is characterized in that it has a Contains calibration device which is constructed so that that with the measuring part connected part (6 or 11) can be displaced by a known amount against the part connected to the fastener tape (7 bzYvT. 12). 6. Sensor according to 1, characterized in that the distance of the Holes in the fastener tape (13) or the links of the fastener chain (8) is so large that it has a known measurement error of z. B. corresponds to 1%.