TWM583758U - Peripheral circulation adjustment system - Google Patents

Abstract

The present disclosure provides an adjustment system for limb peripheral circulation, comprising: a housing body, a temperature control module, and a pressure control module. The accommodating body comprises an insulating layer, forming an accommodating space for accommodating a limb end of a body; a pressing layer disposed outside the insulating layer; and a fluid heat conducting layer disposed outside the pressing layer, comprising a a fluid sensing element disposed on the inner side of the insulating layer for measuring a temperature of the accommodating space to generate a temperature sensing signal; and a pressure sensing element disposed inside the insulating layer for determining the accommodating The pressure of the space creates a pressure sensing signal. The temperature control module and the pressure control module respectively adjust the temperature and pressure of the accommodating space according to the temperature sensing signal and the pressure sensing signal. Thereby, the effect of regulating the peripheral circulation of the limb of the individual can be achieved.

Description

Regulating system for regulating limb peripheral circulation

The present invention relates to an adjustment system that regulates peripheral limb circulation, and in particular, an adjustment system that adjusts the temperature and pressure provided to the distal end of the limb.

Cancer chemotherapy targets, although effective in inhibiting cancer cell growth, can also cause a variety of complications. Because chemical drugs are brought to the body along with the circulation of body fluids during chemotherapy, patients who are treated with chemotherapy are often left with nerves, blood vessels, or lymphatic vessels at the ends of the nerves, and are prone to side effects such as numbness of hands and feet, blackening of the limbs, and hair loss. It is extremely inconvenient to cause life.

Generally, the amount of drug accumulated in the distal extremities is reduced by lowering the peripheral circulation of the limbs by cooling. At present, there is a head-mounted cooling device system, which can reduce the concentration of the drug at the end of the cycle, thereby improving the incidence of the chemical treatment. However, although low temperature can reduce the circulation rate, the human body has limited tolerance to low temperature, and it is impossible to keep limb distal ends (such as hands and feet) in a low temperature environment for a long time. Therefore, the regulation of limb peripheral circulation is still limited only by the method of lowering the temperature.

In view of this, there is a need in the related art for a system for effectively regulating the peripheral circulation of a limb in a chemotherapeutic process, thereby reducing patient discomfort and improving medical quality.

The novel content is intended to provide a simplified summary of the disclosure in order to provide a basic understanding of the disclosure. This Summary is not an extensive overview of the disclosure, and is not intended to identify key/critical elements of the novel embodiments or the scope of the invention.

One aspect of the present invention relates to an adjustment system for regulating the circulation of limbs of a body, comprising: a housing body for receiving a limb distal end, a temperature control module, and a pressure control module. The accommodating body comprises an insulating layer for forming an accommodating space for accommodating the distal end of the individual limb; a pressing layer disposed outside the insulating layer; and a fluid heat conducting layer comprising a fluid medium, wherein the fluid is thermally conductive The layer is disposed outside the pressing layer; a temperature sensing component is disposed on the inner side of the insulating layer for measuring a temperature of the receiving space to generate a temperature sensing signal; and a pressure sensing component is disposed at the The inside of the insulating layer is used to measure a pressure of the accommodating space to generate a pressure sensing signal. Furthermore, the temperature control module is configured to adjust the temperature of the accommodating space according to the temperature sensing signal; and the pressure control module is configured to adjust the pressure of the accommodating space according to the pressure sensing signal. Thereby, the temperature and pressure of the accommodating space can be adjusted through the temperature sensing signal and the pressure sensing signal of the accommodating space to adjust the limb peripheral circulation of the individual.

According to an embodiment of the present invention, the temperature control module includes a temperature control component coupled to the temperature sensing component, the thermal insulation layer, and the fluid thermal conductive layer to receive and process the temperature sensing signal and generate A first temperature control signal and a second temperature control signal are respectively adjusted to adjust the temperature of the accommodating space and adjust the flow of the fluid medium.

According to an embodiment of the present invention, the pressure control module includes a pressure control component coupled to the pressure sensing component and the pressurized layer to receive and process the pressure sensing signal and generate a pressure control signal. To adjust the pressure of the accommodating space.

As mentioned above, the pressure control module further comprises an air pump connected to the pressure control element and the pressure layer.

According to another embodiment of the present invention, the adjustment system further includes a blood oxygen sensing element disposed inside the thermal insulation layer to sense a blood oxygen value of one of the limb distal ends.

As described above, the pressure control module includes a pressure control component coupled to the pressure sensing component, the blood oxygen sensing component, and the pressing layer to receive and process the pressure sensing signal and the blood oxygen The value is generated and a pressure control signal is generated to adjust the pressure in the accommodating space.

According to an embodiment of the present disclosure, the thermal insulation layer comprises a uniform cooling unit and a thermal insulation material, wherein the refrigerating unit is disposed on the thermal insulation material.

According to some embodiments of the present disclosure, the aforementioned insulating material is selected from the group consisting of acrylic resins, carboxymethyl cellulose, xanthan gum, galactomannan polymers, and propylene glycol.

According to an embodiment of the present invention, the pressurizing layer has a gas filled therein to generate the pressure of the accommodating space.

According to an embodiment of the invention, the fluid medium is water.

Through the above configuration, the mediation system of the present invention can adjust the temperature and pressure of the accommodating space by measuring the temperature/pressure sensing signal generated by the temperature and pressure in the accommodating space, corresponding to the generated temperature control signal and the pressure control signal. In order to achieve effective adjustment of the individual's limb peripheral circulation effect and purpose.

The basic spirit and other novel objects of the present invention, as well as the technical means and implementations of the present invention, can be readily understood by those of ordinary skill in the art.

In order to make the description of the present disclosure more detailed and complete, the following description of the embodiments of the present invention and the specific embodiments thereof are set forth. The features of various specific embodiments, as well as the method steps and sequences thereof, are constructed and manipulated in the embodiments. However, other specific embodiments may be utilized to achieve the same or equivalent function and sequence of steps.

Unless otherwise defined in the specification, the meaning of the scientific and technical terms used herein is the same as that of ordinary skill in the art. In addition, the singular noun used in this specification covers the plural of the noun in the case of no conflict with the context; the plural noun of the noun is also included in the plural noun used. In particular, the singular forms "a" and "the"

The present disclosure provides an adjustment system for limb peripheral circulation that can be used to adjust the limb tip circulation of a body. The adjustment system comprises: a receiving body, a temperature control module and a pressure control module. The accommodating body comprises an insulating layer for forming an accommodating space for accommodating the distal end of the individual limb; a pressing layer disposed outside the insulating layer; and a fluid heat conducting layer comprising a fluid medium, wherein the fluid is thermally conductive The layer is disposed outside the pressing layer; a temperature sensing component is disposed on the inner side of the insulating layer for measuring a temperature of the receiving space to generate a temperature sensing signal; and a pressure sensing component is disposed at the The inside of the insulating layer is used to measure a pressure of the accommodating space to generate a pressure sensing signal. Furthermore, the temperature control module is configured to adjust the temperature of the accommodating space according to the temperature sensing signal; and the pressure control module is configured to adjust the pressure of the accommodating space according to the pressure sensing signal. Thereby, the temperature sensing signal and the pressure sensing signal of the accommodating space can be adjusted to adjust the temperature and pressure of the accommodating space to adjust the circulation of the limb of the individual.

An embodiment of the adjustment system of the present disclosure will be described below in conjunction with the drawings.

At the same time, in conjunction with FIGS. 1A to 1C, the adjustment system 1 and its components are respectively an embodiment of the disclosure. In the present embodiment, the adjustment system 1 includes a receiving body 11 , a temperature control module 12 , and a pressure control module 13 . Specifically, the temperature control module 12 and the pressure control module 13 are respectively connected to the accommodating body 11 to constitute the adjustment system 1 of the present disclosure.

As previously stated, the containment body 11 of the present disclosure substantially comprises a multi-layer structure and a plurality of sensing elements to facilitate temperature and pressure feedback regulation. Specifically, the accommodating body 11 includes a heat insulating layer 111, a pressing layer 112, a fluid heat conductive layer 113, a temperature sensing element 1121, and a pressure sensing element 1122.

As shown in FIG. 1C, the heat insulating layer 111 is bent to form the accommodating space 1110, so that the accommodating body 11 has a corresponding opening 1115, so that the limb end of one body can be put into the accommodating space 1110.

According to a specific embodiment of the present disclosure, the hand, the foot, and the head can be placed in the accommodating space 1110. Specifically, the shape of the accommodating space 1110 and the accommodating body 11 may conform to a specific type of limb tip to be applied, and is not limited to the shapes illustrated in the present disclosure and the drawings. For example, the accommodating body 11 may be formed into a glove shape according to the shape of the hand, or may be formed into a sock shape according to the shape of the foot, or may be formed into a hat shape according to the shape of the head.

According to one of the non-essential embodiments, the outer side of the accommodating body 11 of the present disclosure may include a rigid outer casing for limiting the maximum ductile volume of the heat insulating layer, the pressing layer and the fluid heat conducting layer. 1B and 1C of the present disclosure illustrate one type of acrylic outer casing 1105 exemplarily, but the shape and material can be adjusted according to actual needs according to the needs of those skilled in the art, and are not subject to the present disclosure. The limit.

According to the present disclosure, since the insulating layer 111 forms an accommodating space 1110, the insulating layer 111 directly contacts the accommodating space 1110, and provides a predetermined temperature to the accommodating space 1110. According to an embodiment of the present disclosure, the heat insulating layer 111 of the accommodating body 11 may have at least one sealed space, and any cold or heat generating component may be placed in the sealed spaces to cool the accommodating space 1110. Or warming effect. At the same time, the dissipation of thermal energy can be prevented by the remaining filler. According to the embodiment of the present disclosure, at least the uniform cooling unit 1111 and the heat insulating material 1112 are disposed in the sealed spaces for giving the housing space 1110 a temperature lower than the body temperature, so as to reduce the circulation of the limb ends. As shown in FIG. 1C, according to an embodiment of the present disclosure, at least the uniform cooling unit 1111 and the heat insulating material 1112 can be disposed in the same sealed space, and the heat insulating material 1112 is disposed on the cooling unit 1111 to constitute the heat insulating layer 111. . According to an embodiment of the present disclosure, the heat insulating material 1112 may be disposed in the same sealed space in such a manner as to cover the refrigeration unit 1111. According to another embodiment, the cooling unit 1111 and the heat insulating material 1112 may also be disposed in the plurality of sealed spaces and isolated from each other. The specific embodiment of the novel refrigeration unit 1111 includes a refrigerant wafer or a micro-cooling wafer, but is not limited thereto. On the other hand, the specific embodiment of the heat insulating material 1112 may be an acrylic resin, carboxymethyl cellulose, xanthan gum, galactomannan polymer, propylene glycol or a combination thereof, but is not limited thereto. According to one embodiment of the present disclosure, the insulating material is a combination of carboxymethyl cellulose and propylene glycol.

According to the embodiment of the present disclosure, the pressurizing layer 112 is disposed on the heat insulating layer 111 to generate pressure by changing the volume of the accommodating space 1110. Specifically, the pressurizing layer 112 has a gas filled therein to generate a pressure against the accommodating space 1110. According to the embodiment of the present disclosure, the pressing layer 112 may also be a sealed chamber with an elastic expansion space, and is filled with a gas or a liquid to press the heat insulating layer 111 disposed on the inner side thereof, thereby accommodating the receiving space 1110. The limbs in the middle give pressure. The blood vessels at the extremities of the limb contract through this pressure to reduce the flow of blood through the extremities of the limb. In accordance with the present disclosure, the gas that can be charged into the pressurized layer 112 contains air, an inert gas, and nitrogen. In one embodiment, the air is introduced into the pressurized layer 112 to apply pressure to the distal end of the limb in the accommodating space 1110. In an alternative embodiment, to effectively charge the pressurized layer 112 with gas, the pressure control module 13 of the present disclosure may include an air pump coupled to the pressure control element 131 and the pressurized layer 112. Specifically, the pressure control component 131 of the pressure control module 13 generates and transmits a pressure control signal to the air pump 132 according to the pressure sensing signal described above, thereby adjusting the amount of gas charged into the pressurized layer 112. A suitable air pump can be selected according to the general knowledge in the art using a suitable adjustment system and its housing body size and expected intake air volume. According to an embodiment of the present disclosure, the air pump 132 is a micro air pump, but is not limited thereto.

With continued reference to FIG. 1C, in accordance with an embodiment of the present disclosure, the fluid heat conductive layer 113 is disposed outside of the pressurized layer 112 and includes a fluid medium. The fluid medium flows through the fluid heat conductive layer 113 to provide heat balance between the receiving body 11 and the accommodating space 1110 to enhance the accuracy of adjusting the temperature of the adjustment system of the present disclosure. In particular, the fluid medium can be water. A conduit may be provided in the fluid heat conducting layer 113, and the water body may flow along the pipeline to fix the direction of heat energy transfer. According to one embodiment, the fluid heat conductive layer 113 can be coupled to a water-cooled heat sink or be part of the water-cooled heat sink.

As a whole, the accommodating body 11 of the present disclosure includes an accommodating space 1110 formed by the heat insulating layer 111, a pressurizing layer 112 disposed outside the heat insulating layer 111 and covering the heat insulating layer 111, and disposed outside the pressure layer 112 and Preferably, the fluid heat conductive layer 113 of the pressurizing layer 112 is coated to form a multilayer structure capable of simultaneously providing temperature and pressure to the accommodating space 1110. On the other hand, the temperature sensing element 1121 and the pressure sensing element 1122 are both disposed on the inner side of the heat insulating layer 111 (that is, disposed on the side of the accommodating space 1110), thereby measuring the temperature and pressure of the accommodating space 1110, respectively. A temperature sensing signal and a pressure sensing signal are generated.

As described above, and referring to FIG. 1A, when the accommodating space 1110 of the accommodating body 11 accommodates the extremity of a body, the temperature control module 12 can adjust the temperature of the accommodating space 1110 according to the temperature sensing signal. . In an embodiment of the present disclosure, specifically adjusting the temperature of the accommodating space 1110 is performed by the temperature control element 121 included in the temperature control module 12. Specifically, the temperature control component 121 is connected to the temperature sensing component 1121, the heat insulating layer 111, and the fluid heat conductive layer 113 of the accommodating body 11, and receives and processes the temperature sensing signal generated by the temperature sensing component 1121, and correspondingly generates The first temperature control signal transmits the first temperature control signal to the thermal insulation layer 111 to adjust the temperature of the accommodating space 1110. At the same time, the second temperature control signal is generated and transmitted to adjust the fluid thermal conduction layer. 113 The flow of fluid medium. The specific temperature sensing element 1121 of the present disclosure includes temperature sensors known in the art, such as thermocouples, thermistors, resistance temperature detectors, infrared sensors, temperature sensing ICs, and the like, but is not limited thereto.

Similarly, the pressure control module 13 can also adjust the pressure of the accommodating space 1110 according to the pressure sensing signal described above. The pressure of the adjustment accommodating space 1110 can be performed by the pressure control element 131 included in the pressure control module 13. Specifically, the pressure control component 131 is connected to the pressure sensing component 1122 and the pressing layer 112 of the receiving body 11 to receive and process the pressure sensing signal generated by the pressure sensing component 1122, and correspondingly generate a pressure control signal. And transferred to the pressing layer 112 to adjust the pressure of the accommodating space 1110. The specific pressure sensing element 1122 of the present disclosure includes a capacitive pressure sensor and a piezoelectric pressure sensor as are known in the art, but the present invention is not limited thereto.

According to an embodiment of the present disclosure, after the individual puts the limb tip into the accommodating space 1110, if the starting temperature is higher than a temperature setting value, the temperature control module 12 activates the cooling unit 1111 according to the temperature sensing signal. The accommodating space 1110 and the distal end of the limb are cooled, and the temperature is maintained within a predetermined range through the heat insulating material 1112; and the fluid medium is started to flow through the fluid heat conductive layer 113 to accelerate heat dissipation. When the temperature gradually drops to the predetermined range, the temperature control element 121 transmits a shutdown signal to the refrigeration unit 1111 of the thermal insulation layer 111 to stop the cooling operation; and gradually slows down the flow of the fluid medium to reach the accommodation space 1110. Thermal equilibrium. Conversely, after a period of time, if the temperature sensing component 1121 senses that the temperature of the accommodating space 1110 gradually rises beyond the predetermined range, the temperature control module 12 restarts the cooling unit 1111 of the thermal insulation layer 111 to cool down and start. The fluid medium flows into the fluid heat conducting layer 113 to thereby exclude thermal energy.

On the other hand, when the adjustment system is activated, the pressurized layer 112 is filled with air through the air pump 132, and the accommodation space 1110 is pressed to give a predetermined pressure to the distal end of the limb. The pressure sensing element 1122 measures the pressure of the accommodating space 1110. When the predetermined pressure is reached, the pressure control module 13 stops the intake of the pressurized layer 112 by the air pump 132. According to other embodiments of the present disclosure, when the adjustment system is turned off, the pressure control element 131 transmits an exhaust signal to the pressurization layer 112 for exhausting, thereby reducing the pressure.

Through the action mode of the adjusting system, the individual can be placed in the distal end of the living space of the accommodating space 1110 to receive a set temperature and pressure, and the sensing body 11 can be sensed through the temperature control module 12 and the pressure control module 13. And feedback, so that the limb tip can be continuously in the desired temperature and pressure environment for a long time.

Next, another embodiment of the present disclosure will be described with reference to FIG. 2 is a block diagram of an adjustment system 2 in accordance with another embodiment of the present invention. The adjustment system 2 of the present embodiment also includes a housing body 21, a temperature control module 22, and a pressure control module 23. The accommodating body 21 includes a heat insulating layer 211 (forming the accommodating space 2110), a pressurizing layer 212, and a fluid heat conductive layer 213. The temperature control module 22 includes a temperature control element 221. The components included in the housing body 21 and the temperature control module 22, the arrangement thereof, and the functions thereof are the same as those of the housing body 11 and the temperature control module 12, respectively, and are not described herein. The conditioning system 2 of the present disclosure further includes a blood oxygen sensing element 2123 as compared to the conditioning system 1. The blood oxygen sensing element 2123 is disposed inside the insulating layer 211 to sense the blood oxygen value of one of the limb ends of the individual.

Accordingly, the pressure control component 231 of the pressure control module 23 of the present disclosure is simultaneously coupled to the pressure sensing component 2122, the blood oxygen sensing component 2123, and the pressurized layer 212 for receiving and processing the pressure sensing component 2122. The pressure sensing signal and the blood oxygen value generated by the blood oxygen sensing element 2123 generate a pressure control signal to adjust the pressure of the accommodating space 2110.

Specifically, the blood oxygen sensing element 2123 of the present disclosure can measure the blood vessel oxygen concentration of the extremity of the individual, thereby determining the proportion of the blood vessel contraction to estimate the smoothness of the blood circulation. In general, a lower vascular oxygen concentration predicts a greater vasoconstriction and less blood flow through the localized area. According to the concept, a blood oxygen threshold can be set. If the blood oxygen level of the limb is higher than the blood oxygen threshold, the pressure control element 231 can generate a pressurization signal according to the blood oxygen value to the pressure layer 212, and through the air. To increase the pressure on the accommodating space 2110, thereby exerting a squeezing effect on the extremity of the limb, and reducing the blood flow through the distal end of the limb; conversely, if the blood oxygen value of the extremity of the limb is lower than the blood oxygen threshold, the pressure control element 231 generates a decompression signal according to the blood oxygen value to the pressing layer 212 to reduce the pressure on the accommodating space 2110 by releasing the deflation or exhausting, and releasing the squeeze feeling of the distal end of the limb.

In view of such a design, blood flow through a local region of the distal end of the limb can be effectively controlled, and the discomfort caused by the accumulation of the drug at the distal end of the limb can be reduced.

The specific embodiments are set forth below to illustrate certain aspects of the present invention, which are intended to be illustrative of the present invention and are not intended to limit the scope of the invention. It is believed that the skilled artisan can fully utilize and practice the novel without having to over-interpret it after reading the instructions presented herein. All publications cited herein are hereby incorporated by reference in their entirety.

Example 1

In conjunction with Figure 3 of the drawings, the adjustment system 3 of the present disclosure is specifically fabricated as a containment body 31 that can accommodate an individual's hand. As shown in Figure 3. The adjustment system 3 has a rigid outer casing 3105 for securing the shape of the unitary receiving body 31. The accommodating body 31 includes a heat insulating layer 311, a pressurizing layer 312, and a fluid heat conductive layer 313. A thermoelectrically cooled wafer (model: TEC1-199.08, TEC1-127.04, or FROST-75) is used as the refrigeration unit 3111, and is surrounded by a heat insulating material 3112 of carboxymethylcellulose and propylene glycol, and is packed in polyvinyl chloride ( PVC) or an Ethylene Vinyl Acetate (EVA) material to form an insulating layer 311. The accommodating space 3110 formed by the heat insulating layer 311 is in contact with the skin of the individual hand, and a sterilized cotton cloth is further disposed.

Further, air is injected into the pressurizing layer 312 through the micro air pump 332 to press the heat insulating layer 311 to compress the accommodating space 3110. At the same time, since the temperature of the thermoelectrically cooled wafer can be lowered, the fluid heat conduction layer 313 of the present embodiment may include a conduit W through which the water flowing through the conduit W is coupled to the external water-cooling system S.

When the adjustment system of the embodiment is used, a temperature setting value (for example, 5-10 ° C) is first set, and then the individual puts his or her hand into the accommodating space 3110, and determines that the hand position can correspond to the temperature sensing element 3121. After the position of the pressure sensing element 3122 and the blood oxygen sensing element 3123 is set, the cooling unit 3111 is started to cool down and the air pump 332 is inflated to apply pressure. The individual's hand is placed for 15-20 minutes. During the placement, the temperature sensing element 3121, the pressure sensing element 3122, and the blood oxygen sensing element 3123 can sense the hand temperature, the surface pressure, and the blood oxygen value, and give the temperature. The control module 32 and the pressure control module 33 are regulated. After 20 minutes of treatment, the condition of the individual's hand blood circulation was recorded for subsequent clinical use.

Example 2

The adjustment system of the present disclosure can also be specifically made to include a housing body 41 conforming to the shape of the hand in accordance with Fig. 4 of the drawings. The adjustment system of this embodiment is similar to the adjustment system 3 and all contain the same elements. Please refer to the above for the description of the same components, and details are not described here. The largest difference between the present embodiment and the embodiment 1 is that the outer casing 4105 of the accommodating body 41 has an oblique projection area, and the accommodating body 41 corresponds to the accommodating space 4110 formed by the inner thermal insulation layer (not shown). The shape of the portion is such that the corresponding opening (4115, 4115') is provided on the outer casing 4105. In use, the individual places the hand into the receiving body 41 from the opening 4115, and the thumb can pass through the opening 4115' of the oblique protruding region.

The specific embodiments of the present invention are disclosed in the above embodiments, and are not intended to limit the present invention. Those of ordinary skill in the art to which the present invention pertains, without departing from the spirit and scope of the present invention, Various changes and modifications may be made thereto, and the scope of protection of the present invention is defined by the scope of the accompanying claims.

1, 2, 3‧‧‧ adjustment system

11, 21, 31, 41‧‧‧ accommodating the ontology

1105, 3105, 4105‧‧‧ outer casing

111, 211, 311‧ ‧ insulation

1110, 2110, 3110, 4110‧‧‧ accommodating space

1111, 3111‧‧‧ Refrigeration unit

1112, 3112‧‧‧Insulation materials

1115, 3115, 4115, 4115’‧‧‧ openings

112, 212, 312‧‧ ‧ compression layer

113, 213, 313‧‧‧ fluid heat conduction layer

1121, 2121, 3121‧‧‧ Temperature sensing components

1122, 2122, 3122‧‧‧ Pressure sensing components

12, 22, 32‧‧‧ Temperature Control Module

121, 221‧‧‧ temperature control components

13, 23, 33‧‧‧ Pressure Control Module

131, 231‧‧‧ Pressure Control Components

132, 232, 332‧‧‧ air pump

2123, 3123‧‧‧ blood oxygen sensing components

S‧‧‧Water cooling system

W‧‧‧ catheter

To make the above and other objects, features, advantages and embodiments of the present invention more apparent, the description of the drawings is as follows:

1A is a system block diagram of an adjustment system 1 according to an embodiment of the present invention;

1B is a perspective view of the housing body 11 of the adjustment system 1 according to an embodiment of the present invention;

1C is a cross-sectional view of the housing body 11 according to the section line L1-L1 of FIG. 1B;

2 is a system block diagram of an adjustment system 2 according to another embodiment of the present invention;

FIG. 3 is a schematic diagram showing the use of the adjustment system 3 according to an embodiment of the present invention;

4 is a perspective view of the housing body 41 according to another embodiment of the present invention.

The various features and elements in the figures are not drawn to scale, and are in the In addition, similar elements/components are referred to by the same or similar element symbols throughout the different drawings.

Claims (10)

An adjustment system for regulating the circulation of limbs of a body, comprising:
a containment body accommodating the distal end of the limb, comprising:
An insulating layer for forming an accommodating space for accommodating the distal end of the individual;
a pressing layer disposed outside the insulating layer;
a fluid heat conducting layer comprising a fluid medium, wherein the fluid heat conducting layer is disposed outside the pressing layer;
a temperature sensing component disposed on the inner side of the insulating layer for measuring a temperature of the accommodating space to generate a temperature sensing signal; and a pressure sensing component disposed on the inner side of the insulating layer for determining the capacitance a pressure of the space to generate a pressure sensing signal;
a temperature control module for adjusting the temperature of the accommodating space according to the temperature sensing signal; and a pressure control module for adjusting the pressure of the accommodating space according to the pressure sensing signal. The adjustment system of claim 1, wherein the temperature control module comprises:
a temperature control component coupled to the temperature sensing component, the insulating layer, and the fluid heat conducting layer to receive and process the temperature sensing signal and generate a first temperature control signal to adjust the receiving space The temperature; and a second temperature control signal to adjust the flow of the fluid medium. The adjustment system of claim 1, wherein the pressure control module comprises:
A pressure control component is coupled to the pressure sensing component and the pressurization layer to receive and process the pressure sensing signal and generate a pressure control signal to adjust the pressure of the accommodating space. The adjustment system of claim 3, wherein the pressure control module further comprises an air pump connected to the pressure control element and the pressure layer. The adjustment system of claim 1, further comprising a blood oxygen sensing element disposed inside the thermal insulation layer to sense a blood oxygen value of one of the limb distal ends. The adjustment system of claim 5, wherein the pressure control module comprises:
a pressure control component coupled to the pressure sensing component, the blood oxygen sensing component and the pressing layer to receive and process the pressure sensing signal and the blood oxygen value, and generate a pressure control signal to adjust The pressure of the accommodation space. The conditioning system of claim 1, wherein the insulation layer comprises a uniform cooling unit and a thermal insulation material, wherein the refrigeration unit is disposed on the thermal insulation material. The conditioning system of claim 7, wherein the insulating material is selected from the group consisting of acrylic resins, carboxymethyl cellulose, xanthan gum, galactomannan polymers, and propylene glycol. The conditioning system of claim 1, wherein the pressurized layer has a gas filled therein to generate the pressure of the accommodating space. The conditioning system of claim 1 wherein the fluid medium is water.