RU47526U1 - DEVICE FOR THE EVALUATION OF PHYSICAL PROPERTIES OF BIOLOGICAL LIQUIDS - Google Patents

Abstract

The utility model relates to laboratory medical equipment and can be used to study liquid biological media. The objective of the utility model is to obtain information about the optical and geometric parameters of a lying drip sample of a biological fluid. The device comprises a primary converter chamber in which a plate made of a hydrophobic, transparent material is placed between a vertically coaxial source and an optical radiation receiver to accommodate a drop sample of the biological fluid under investigation. Moreover, the optical radiation source is located under the drip sample, and the optical radiation receiver is above it, while the optical radiation source is connected to a stable current source that is connected to the power source, and the optical radiation receiver is connected to the recording source through the photo current amplifier connected to the power source device. A video camera lens is located on the side wall of the primary converter chamber, located on the same horizontal axis as a lying drop of the test sample and is focused on it. The camcorder is connected to a personal computer. A temperature sensor and a heating element are placed in the chamber of the primary converter, which are connected to a thermoregulation unit connected to a power source, as well as a water evaporator. Evaporation of water occurs from the surface of the hygroscopic material glued to the inner surface of the chamber of the primary transducer, the lower edge of which is lowered into the channel with water, having an external vessel for refueling. The video surveillance channel allows you to capture and evaluate the geometric parameters of the profile of the drip sample. The vertical optical measuring channel provides information on the optical properties of the sample. The saturated vapor atmosphere created by the water evaporator reduces the evaporation of droplet samples.

Description

The utility model relates to laboratory medical equipment and can be used to study physico-chemical, optical properties, as well as assess the dynamics of biophysical and biochemical processes in liquid biological media.

The course of biological processes is associated with many physical and chemical phenomena. In particular: a change in the mechanical-dynamic properties, electrical conductivity, dispersion of the medium, the surface energy of individual cells and solutions, a change in temperature and optical-spectral characteristics of the sample. These phenomena can be detected by physical methods and underlie the study of biological media.

A device is known for determining the physical properties, and in particular, the surface energy of biological cells, by changing the contact angle of a drop of a studied biological fluid, selected as a prototype [Immunology. Research Methods. Ed. I. Lefkovitsa, B. Pernis. Per. with the English., M. "Mir", 1983, p. 152-154].

The device consists of separate blocks mounted on an optical bench: a focused light source, adjustable in xyz-directions of the horizontal surface, on which a sample of the studied biological fluid, a lens with a variable focal length, a prism for reflecting the projected light beam onto the screen from frosted glass for measurements. In this case, the contact angle is measured by the enlarged projection of the droplet profile on the matte screen.

The disadvantage of this device is the low measurement accuracy due to the fact that the determination of the contact angle

performed visually, while objectivity and data value are reduced. In addition, the study time is limited due to the evaporation of the investigated drip sample.

The objective of the utility model is to increase the accuracy of measurements, reduce the evaporation rate of the studied samples, expand the number of recorded physical parameters of droplet samples of biological fluids.

The proposed device, like the prototype, contains a horizontal surface for placement on it in the form of a lying drop of the test sample and a system for acquiring an image of the lateral projection of this drop.

In contrast to the prototype, the horizontal surface for the placement of drip samples is made in the form of a plate of hydrophobic, transparent material and placed in the working volume of the primary converter chamber, isolated from the external environment, between a vertically coaxial source and receiver of optical radiation (measuring optical channel). Moreover, the optical radiation source is located under the drip sample, and the optical radiation receiver is located above it. An optical radiation source is connected to a stable current source that is connected to a power source, and an optical radiation receiver is connected to a recording device through a photocurrent amplifier connected to a power source. A video camera lens is located on the side wall of the primary converter chamber, located on the same horizontal axis as a lying drop of the test sample and is focused on it. The camcorder is connected to a personal computer. A temperature sensor and a heating element are placed in the chamber of the primary converter, which are connected to a thermoregulation unit connected to a power source, as well as a water evaporator.

A hygroscopic material glued to the inner surface of the primary chamber is used as a water evaporator

transducer, the lower edge of which through a slot is lowered into a channel with water connected to an external vessel for refueling.

The use of a video camera drop to obtain an image, with the transfer of information to a computer, makes it possible to automatically process the image of the drop profile, which accordingly increases the accuracy and objectivity of measurements. Placing the droplet samples in the chamber of the primary transducer with high humidity and stabilized temperature reduces their evaporation rate, and helps to increase the accuracy and repeatability of the indicators obtained in the study. In addition, a decrease in the evaporation of samples allows an increase in the observation time and, accordingly, it is possible to evaluate the dynamics of the processes occurring in the samples. The introduction of a vertical measuring optical channel provides additional information about the optical properties of the test sample.

Figure 1 shows a structural diagram of a device for studying the physical properties of biological fluids.

Figure 2 presents the design of the chamber of the primary transducer of the device for assessing the physical properties of biological fluids.

The device (Fig. 1) consists of a chamber of the primary transducer 1 (PP), including a vertically coaxially located optical radiation source 2 (AI) and an optical radiation receiver 3 (PI), between which a cuvette with an investigated liquid droplet 4 (PR) is placed. The composition of the chamber of the primary Converter 1 (PP) also includes a temperature sensor 5 (TD) and a heating element 6 (NE). In the side wall of the camera of the primary Converter 1 (PP) is integrated the lens of the video camera 7 (VK), focused on the drip sample 4 (PR). The camcorder 7 (VK) is electrically connected to the video input board of a personal computer 8 (PC). In addition, the device includes:

a stable current source 9 (IST) connected to an optical radiation source 2 (AI); a thermoregulation unit 10 (TP), electrically connected to a temperature sensor 5 (TD) and a heating element 6 (NE); a photocurrent amplifier 11 (US), electrically connected to an optical radiation receiver 3 (PI) and a recording device 12 (RU). The power source 13 (IP) is electrically connected to the thermoregulation unit 10 (TP), a stable current source 9 (IST) and a photocurrent amplifier 11 (US).

Figure 2 presents the design of the chamber of the primary transducer 1 (PP), which is made in the form of an all-metal body 14 with a cavity milled inside (working volume) 15 for placing the cuvette 16. The working volume 15 of the camera of the primary transducer 1 (PP) is isolated from the external environment hinged lid 17 with a gasket.

In the camera housing of the primary transducer 1 (PP), a through vertical channel is made, in the upper part of which, relative to the working volume 15 of the camera of the primary transducer 1 (PP), on the movable plunger 18, with the possibility of vertical movement in the channel, an optical radiation receiver 3 is placed (PI). In the channel of the lower part of the camera housing of the primary transducer 1 (PP) is placed, mounted on the faceplate 19, the optical radiation source 2 (AI). The plate 19 is held by three spring-loaded screws 20, also performing the function of aligning the optical radiation source 2 (AI).

Above the optical radiation source 2 (II) in the horizontal groove of the chamber of the primary transducer 1 (PP), there is a disk 22 rotating on the axis 21, having perforated diaphragm holes 23 with a diameter of 1 mm to 5 mm along its perimeter. The disk 22 from spontaneous rotation in certain positions is held by a spring clip 24.

The cuvette 16 is a metal plate with dimensions that allow it to be accurately fixed in the working volume of the chamber of the primary transducer 1 (PP) and having a hole coaxial with the vertical channel for accommodating disposable inserts 25 of a transparent inert hydrophobic material.

A hygroscopic material 26 is glued on the inner rear wall of the chamber of the primary transducer 1 (PP), the lower edge of which is lowered through a slot into a horizontal channel 27 with water connected to an external refueling vessel 28.

On the outer rear wall of the chamber of the primary Converter 1 (PP) has a heating element 6 (NE). The temperature sensor 5 (TD) is located in the working volume of the chamber of the primary transducer 1 (PP) near the drip sample of liquid 4 (PR) and is fixed through a special hole in the upper part of the housing of the chamber of the primary transducer 1 (PP).

In the side walls of the camera are made: a window closed by transparent glass 29 to observe the droplet shape using a video camera and a frosted glass window 30 to illuminate the subject when shooting.

As a source of optical radiation 2 (AI), an LED or a laser diode can be used, with the spectral characteristics necessary for research problems. The stable current source 9 (IST) is assembled on an operational amplifier according to one of the generally accepted schemes [Gutinikov B.C. Integrated electronics in measuring devices. - 2nd ed., Revised. and add. - L .: Energoatomizdat, 1988, p. 61-84]. The receiver of optical radiation 3 (PI) can serve as a photodiode or other photo-recording device, the perceived spectral range of which coincides with the spectral characteristics of the source of optical radiation 2 (AI). The photocurrent amplifier 11 (US) is made on the operational amplifier according to the current-voltage conversion scheme, where the photodiode used as a receiver of optical radiation 3 (PI) is turned on in photovoltaic mode. Amplifier of photocurrent 11 (CSS)

has the ability to adjust the gain. As a temperature sensor 5 (TD), a thermistor is used, which is included in one of the shoulders of the bridge measuring transducer of thermoregulation unit 10 (TP), made on an operational amplifier. The heating element 6 (NE), wire type, with a power of up to 15 W, is mounted on the rear wall of the camera housing of the primary Converter 1 (PP). Other types of heaters may be used. The recording device 12 (RU) may be a digital voltmeter or any other device for measuring and processing electrical slowly varying signals. The power supply 13 (UT) is made according to the traditional scheme with a network transformer and a stabilized output voltage of ± 15 V. A personal computer 8 (PC) of the type IBM PC must have a video input card and corresponding software.

During operation, an accurately metered drop sample of the studied biological fluid 4 (PR) is introduced into the chamber of the primary transducer 1 (PP) with the cover 17 open on the cuvette 16, which is applied with a pipette dispenser to the surface of a transparent, hydrophobic liner 25 located in the opening of the cuvette 16.

Due to the operation of the thermoregulation unit 10 (TP), controlled by the signal of the temperature sensor 5 (TD), the required temperature is maintained in the chamber of the primary converter 1 (PP). As a result of the evaporation of distilled water from the surface of the hygroscopic material 26, an atmosphere of saturated steam is created in the working volume of the chamber of the primary transducer 1 (PP), which eliminates the drying of the studied droplet sample 4 (PR).

By moving the plunger 18 vertically, with the optical radiation receiver 3 (PI) located on it, the latter is installed at the required distance from the drip sample 4 (PR). By rotating the disk 22 with the diaphragm holes 23, the required diameter of the probe light flux from the optical source is established

radiation 2 (AI). The spring clip 24 accurately locks the disc 22 in the position corresponding to the selected diaphragm.

Primary information about the optical properties of a droplet sample 1 (PR) of a biological fluid is obtained when it is illuminated by a light flux from an optical radiation source 2 (II). Passing through the drip sample 4 (PR), the light flux enters the optical radiation receiver 3 (PI). Due to the low transparency of many biological fluids, the electric signals from the optical radiation receiver 3 (PI), as a rule, have a small value and preliminary amplification is necessary, performed by the corresponding photocurrent amplifier 11 (US). Depending on the optical density of the biological fluid, the gain of the photocurrent amplifier 11 (US) is selected. Next, an amplified electrical signal is supplied to the recording device 12 (RU), from which the readings are taken, based on which the optical properties of the droplet sample 4 (PR) and their change as a result of any processes in the drip sample 4 (PR) are judged.

Information on the geometry of the drip sample 4 (PR) is recorded by the video camera 7 (VK) and transmitted via the video input card to the personal computer 8 (PC), where it is monitored, as well as further processing and storage. Based on the obtained digitalized image of the projection of a drop sample 4 (PR) of the test liquid, an automatic analysis of its geometric parameters, including the wetting angle, is possible.

The device allows you to study the optical properties of samples and the dynamics of various biological and physico-chemical processes associated with the aggregation and sedimentation of biological cells and other dispersed particles in liquid optically transparent media, as well as associate them with a change in the geometry of the sample drop, which is recorded using a horizontal video channel .

Claims (2)

1. A device for assessing the physical properties of samples of biological fluids, containing a horizontal surface for placement on it in the form of a lying drop of the test sample and a system for acquiring an image of the lateral projection of this drop, characterized in that the horizontal surface for placing the drop samples is made in the form of a plate of hydrophobic , transparent material and placed in an isolated working volume of the chamber of the primary transducer between vertically coaxially located source and receiver of optical and radiation, and the optical radiation source is located under the drip sample, and the optical radiation receiver is above it, while the optical radiation source is connected to a stable current source that is connected to the power source, and the optical radiation receiver is connected through the photocurrent amplifier connected to the power source to the recording device, in addition, a video camera lens is located in the side wall of the camera of the primary converter, located on the same horizontal axis as a lying drop of the studied and focused on it, and the video camera is connected to a personal computer, and a temperature sensor and a heating element are placed in the primary converter chamber, which are connected to a thermoregulation unit connected to a power source, as well as a water evaporator. 2. The device according to claim 1, characterized in that a hygroscopic material is used as a water evaporator, glued to the inner surface of the chamber of the primary transducer, the lower edge of which is lowered through a slot into a channel with water connected to an external vessel for refueling.