TR2022017381A2 - WIRELESS IMAGING ELECTRODE SYSTEM - Google Patents

Abstract

This invention is related to a wireless imaging electrode system that transfers data via radio frequency by placing a transmitter on the electrodes attached to the patient's body and a receiver on medical imaging devices in order to display body signals through wireless signal transmission. Transmitter component (1), which wirelessly transmits the electrical signals received from the electrode (3), receiver component (2), which captures the electrical signals coming from the transmitter component (1) and transfers them to the electronic device (4), transmitter microcontroller (7), which defines a customized identity to the electrical signals. The RF transmitter (5) transfers the special ID signals defined by the microcontroller (7) to the receiver component (2), the RF receiver (6) to which the special ID signals received from the RF transmitter (5) are transmitted, the special ID signals transferred to the RF receiver (6) according to the defined signal IDs. The receiver microcontroller (8), which converts it into a signal that can be read by existing systems and transmits it to the display device (4) monitor, uses artificial intelligence algorithms (artificial intelligence algorithms) that enable high and fast data transfer between the transmitter component (1) and the receiver component (2) and obtain meaningful data by evaluating the relevant data. 15) is included.

Description

DESCRIPTION WIRELESS IMAGING ELECTRODE SYSTEM Technological Field: This invention is related to the wireless imaging electrode system, which transfers data via radio frequency by placing a transmitter on the electrodes attached to the patient's body and a receiver on medical imaging devices in order to display body signals through wireless signal transmission. State of the Art: Today, in order to ensure the connection between the electrodes attached to the patient's body and medical imaging devices, a communication cable must be connected to the electrodes. In this case, the signals of the patients are transmitted to the imaging device via cables. In addition to connecting the cables together, one side is used to transfer signals by connecting to the electrodes and the other side to the imaging device. Due to the excess equipment required for the functioning of the current system, the image crowding caused by devices and cables causes negative emotions such as anxiety, fear and anxiety in the patient. In addition, preventing the conscious patient from making independent in-bed turning movements also makes the patient feel bad psychologically. Patients who are worried about the cables coming out cannot position themselves comfortably while falling asleep, and as a result, they are faced with negative situations such as insomnia, restlessness, delirium and impaired compliance with treatment. These negativities mentioned affect patients psychologically, and due to the confusion in patients who are exposed to them for a long time, situations may occur that may disrupt patient follow-up. For example, due to this restrictive state of the cables, negativities such as the patient feeling like he is tied to a chain as a result of comparing the cables to another object and struggling to get rid of the cables that he sees as a chain, put the healthcare personnel in a difficult situation and cause the process to be prolonged. At the same time, processes such as removing the multi-cable system from the patient's body one by one during patient care practices and reconnecting it after the procedure create a waste of time. Due to the multiple and complex cable system used in the state of the art, the cables attached to both the patient, the device and each other may fold, bend, etc. due to patient movement or incorrect positioning of the personnel. These conditions cause noisy images to be obtained and therefore give results that hinder the complete diagnosis, evaluation and treatment process. Additionally, if the multi-cable system does not come into contact with the patient's body, patient monitoring cannot be performed. This makes it difficult to detect acute conditions that may develop in the patient. In addition, multi-cable system compression etc. Injuries may occur on the patient's body as a result of these situations. At the same time, even if the cables are sterilized, repeated use of the cables for different patients poses a risk of infection. is explained. The present invention relates to wireless electrodes that can be used with electrocardiogram readers. In one embodiment of the present invention, wireless electrodes are housed in a base station. The base station pairs all wireless electrodes via at least one of Bluetooth connectivity, infrared connectivity, and wireless LAN connectivity. The data received from the wireless electrodes are synthesized and transferred to the base station. The base station transmits the data to the electrocardiogram reader. Wireless electrodes are mentioned in the patent application described above. In the current invention, Bluetooth and wireless local network installations are required. The electrode and disposable adhesive probes must be attached to each other with a spring clip placed on the electrode. If these parts become dislodged due to patient movement, signal transmission stops. Here the medical device is an electrocardiogram reader. It is disadvantageous in terms of cost, compatibility and simplicity due to the necessity of using an imaging device compatible with the electrode. The application titled "Electrode" is discussed. The present invention generally relates to a wireless electrode module that can be attached to a disposable electrode strip to capture biopotential voltage signals such as electroencephalograms (EEGs), electrocardiograms (ECGs) or electromyograms (EMGs). It deals with a wireless biopotential monitoring system. This type of device can be conveniently adhered to a patient's skin. In the patent application discussed above, wireless electrodes are mentioned in the present invention. There is a risk of dislodgement of the electrodes or the electrode strip due to the patient's overactive mood, which may be triggered by the patient's restlessness. If these parts break or lose their adhesiveness due to the patient's movement or discomfort, signal transmission stops and situations that may disrupt patient follow-up and evaluation of the disease may occur. Here, in order for the invention to fulfill its functions, the electrode must be used with the medical devices mentioned above. This obligation creates disadvantages in terms of cost, compatibility and simplicity of the system. As a result, it is a device that can overcome the above-mentioned disadvantages and eliminate the complex wiring system in imaging systems, unnecessary stress, anxiety, anxiety, etc. that may occur in the patient due to this chaos. It increases the patient's comfort level by reducing the number of situations, reduces the number of physical connections from equipment to the patient, prevents signal transmission from stopping, prevents the use of imaging devices compatible with electrodes, provides the opportunity to work in areas where there are no external power sources, ensures that medical devices are portable, reduces the workload of healthcare personnel, and enables efficient working. There is a need for a new artificial intelligence-based technology that does not occupy storage space due to excess equipment, provides high sensitivity for accurate diagnosis, diagnosis, evaluation and treatment, provides high accuracy results, is easy to use and install, and is practical. Description of the invention: This invention is a wireless imaging electrode system and its feature is; It transfers data via radio frequency by placing transmitters on electrodes attached to the patient's body and receivers on medical imaging devices in order to display body signals through wireless signal transmission, eliminates the complex cabling system, reduces the number of physical connections from the equipment to the patient, prevents the signal transfer from stopping, and does not require external power sources. A new artificial intelligence-based technology that provides the opportunity to work in areas, ensures that medical devices are portable, does not occupy storage space due to excess equipment, provides high sensitivity, high accuracy results for accurate diagnosis, diagnosis, evaluation and treatment, is easy to use and install, and is practical. is to be. Invention to realize all the purposes mentioned above and which will emerge from the detailed explanation below; It eliminates the cables of bedside monitors used in operating rooms, emergency rooms and intensive care units, and enables data transfer via radio frequency by placing a transmitter on the electrodes attached to the patient and a receiver on the monitor device. By reducing cable complexity and crowding, the invention reduces unnecessary stress, anxiety, anxiety, etc. that may occur in the patient. It increases the comfort level of the patient by reducing the number of situations and enables healthcare professionals to work with high efficiency by reducing their workload. The invention enables conscious patients to easily turn around in bed. In this way, since there is no problem of cables folding, bending or breaking due to patient movement, noisy images are not obtained and incorrect evaluations are prevented. The invention saves both labor and time as it reduces situations that may interrupt the course of treatment, such as removing and attaching cables during patient care practices. At the same time, it allows monitoring of the patient even when the cables are not connected. In this way, possible acute situations are detected immediately and intervened in a timely manner. Thanks to the invention, problems related to insomnia are prevented by eliminating the sleep problems experienced by patients due to the concern that the cables will come off. At the same time, the feeling of restriction that occurs in patients due to cables is eliminated and the possible psychological problems that this feeling may cause are reduced. Thanks to the invention, negative effects that may occur on the patient, such as cable-related head injuries and infection, are prevented. The invention can be easily used in many areas such as intensive care, emergency rooms, operating rooms and inpatient services. Especially in environments that require quick and effective intervention, such as emergency rooms, the elimination of cable crowding increases survival rates. Since there is no obligation to use a compatible imaging device in the system of the invention, it can work in harmony with existing devices. The system of the invention increases efficiency in cases requiring rapid and effective diagnosis, prognosis and intervention, and thus provides financial gain by reducing the length of stay of patients. The system of the invention eliminates the risks such as the electrode falling, breaking or dislodging, and offers simple use without requiring additional installation and adjustment. The structural and characteristic features and all the advantages of the product subject to the invention will be more clearly understood thanks to the figures given below and the detailed explanation written by referring to these figures, and therefore the evaluation should be made by taking these figures and the detailed explanation into consideration. Description of Drawings: The invention will be described with reference to the accompanying drawings, so that the features of the invention will be more clearly understood and appreciated, but the purpose of this is not to limit the invention to these particular embodiments. On the contrary, it is intended to cover all alternatives, modifications and equivalences of the invention that may be included within the scope of the invention as defined by the appended claims. It should be understood that the details shown are for the sole purpose of illustrating preferred embodiments of the present invention and are presented for the purpose of providing the most useful and easily understandable description of both the embodiment of the methods and the rules and conceptual features of the invention. In these drawings; The figure is the view of the transmitter component connected to the body electrode of the system subject to the invention. Figure 12 is the view of the receiving component connected to the imaging device of the system subject to the invention. Figure 3 is the block diagram of the system that is the subject of the invention. The figures that will help understand this invention are numbered as indicated in the attached picture and are given below with their names. Explanation of References: Electrode RF Transmitter RF Receiver Transmitter Microcontroller Receiver Microcontroller RF Power Battery Microcontroller Power Batteries l 1. Body 12. Top Cover 13. Power Input 14. Device Input. Artificial Intelligence Algorithms Disclosure of Invention: Invention; transmitter component (l) that wirelessly transmits the electrical signals received from the electrode (3), receiver component (2) which captures the electrical signals coming from the transmitter component (l) and transfers them to the electronic device (4), transmitter microcontroller (7) which defines a customized identity to the electrical signals, The RF transmitter (5) transfers the special ID signals defined by the microcontroller (7) to the receiver component (2), the RF receiver (6) to which the special ID signals received from the RF transmitter (5) are transmitted, the special ID signals transferred to the RF receiver (6) according to the defined signal IDs. The receiver microcontroller (8), which converts it into a signal that can be read by existing systems and transmits it to the display device (4) monitor, uses artificial intelligence algorithms (artificial intelligence algorithms) that provide high and fast data transfer between the transmitter component (1) and the receiver component (2) and enable meaningful data to be obtained by evaluating the relevant data. 15) includes. The invention includes the RF transmitter (5) placed on the body (11). The invention includes the transmitter microcontroller (7) and the RF supply battery (9) that feeds the RF transmitter (5) to provide power to the transmitter component (1). The invention includes microcontroller power batteries (10) that feed the transmitter microcontroller (7). The invention includes the transmitter component (1) consisting of the top cover (12) that covers the body (11) containing the electronic parts of the system. The invention includes the receiver component (2) consisting of the RF receiver (6), receiver microcontroller (8), power input (13) and device input (14) placed on the body (11). The invention includes the transmitter component (1) that is mounted externally to the electrode (3) that transmits the electrical signal by being adhered to the patient's body by the adhesive surface it contains. The invention includes a receiver component (2) that enables data transfer via radio frequency by receiving electrical signals from the transmitter component (1). The invention includes the imaging device (4) that enables the signals to be easily separated by having a specific identity of the signals coming from the transmitter component (1) integrated into the electrode (3). The invention includes the receiver component (2) connected to the imaging device (4). The invention includes a receiver component (2) that receives circuit power from the network connected to the power input (13). The invention includes a receiver component (2) that is connected to the imaging device (4) via the device input (14). Detailed Explanation of the Invention: The invention basically consists of the transmitter component (1), receiver component (2), body electrode (3) and any imaging device (4). The transmitter component (1) included in the invention; RF transmitter (5) placed on the body (11), transmitter microcontroller (7), RF supply battery (9) that feeds the RF transmitter (5) to provide power to the transmitter component (1), microcontroller supply batteries (10) that feed the transmitter microcontroller (7). and the upper cover (12) that covers the body (11). The receiver component (2) included in the invention consists of the RF receiver (6), receiver microcontroller (8), power input (13) and device input (14) placed on the body (11). The invention enables data transfer to be carried out via radio frequency by integrating the transmitting component (1) into the electrode (3), which transfers the electrical signal by affixing it to the patient's body, and the receiving component (2) into the device (4). The invention consists of a transmitter component (1) that can be mounted externally to the body electrode (3) and a receiver component (2) that will be connected to the imaging device (4) via the device input (14). In the system of the invention, the transmitter component (1) is used to wirelessly transmit the electrical signals received through the electrode (3) to the device (4) where the receiver (2) is located. In the system of the invention, a customized identity is defined to the electrical signals received through the electrode (3) by the microcontroller (7) located in the transmitter component (1). In the system of the invention, specially identified signals defined by the transmitter microcontroller (7) in the transmitter component (1) are transferred to the receiver component (2) via the RF transmitter (5) module. In the invention, specially identified signals received from the RF receiver (6) located in the receiver component (2) and the RF transmitter (5) located in the transmitter component (1) are transferred to the RF receiver (6) in the receiver component (2). In the system of the invention, the signals with the special ID transferred to the RF receiver (6) are converted into a signal that can be read by existing systems according to the signal IDs defined by the receiver microcontroller (8) and transmitted to the monitor of the display device (4). In the invention, the signals coming from the transmitter component (1) integrated into the electrode (3) have a specific identity, allowing the signals to be easily separated by the receiver component (2) connected to the imaging device (4). In the operation of the system subject to the invention, high and fast data transfer is carried out through a specially developed software that includes artificial intelligence algorithms (15). In the invention, the receiver component (2) provides the circuit power from the network connected to the power input (13). The maximum height of the transmitter component (1) of the invention is 20 mm.TR TR

Claims (12)

l- The invention is related to the wireless imaging electrode system and its feature is; The transmitter component, which wirelessly transmits the electrical signals received from the electrode (3), the transmitter microcontroller (7), which captures the electrical signals coming from the transmitter component (l) and defines a customized identity to the electrical signals to the electronic device, and the signals with a special identity defined by the microcontroller (7) to the receiver component (2). transmitting RF transmitter (5), RF receiver (6) to which the specially identified signals received from the RF transmitter (5) are transmitted, the specially identified signals transferred to the RF receiver (6) are converted into a signal that can be read by existing systems according to the defined signal identities and transmitted to the display device (4) monitor. It contains artificial intelligence algorithms (15) that enable high and fast data transfer between the receiver microcontroller (8), transmitter component (1) and receiver component (2) and obtain meaningful data by evaluating the relevant data. 2- The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by containing the RF transmitter (5) placed in the body (1 l). 3- The claim is related to the wireless imaging electrode system mentioned and its feature is; The transmitter microcontroller (7) is characterized by containing the RF supply battery (9) that feeds the RF transmitter (5) to provide power to the transmitter component (1). 4- The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by containing microcontroller power batteries (10) that feed the transmitter microcontroller (7). The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by containing a transmitter component (1) consisting of a top cover (12) that covers the body (11) containing the electronic components of the system. The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by the receiver component (2) consisting of the RF receiver (6), receiver microcontroller (8), power input (13) and device input (14) placed on the body (11). The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by the fact that it contains a transmitter component (l) that is mounted externally to the electrode (3) that transmits the electrical signal by being adhered to the patient's body by the adhesive surface it contains. The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by containing a receiver component (2) that enables data transfer via radio frequency by receiving the electrical signals coming from the transmitter component (l). The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by the signals coming from the transmitter component (1) integrated into the electrode (3) having a specific identity and containing the imaging device (4) that enables the signals to be easily separated. 10- It is related to the wireless imaging electrode system according to Claim 1 or Claim 9, and its feature is; It is characterized by containing the receiver component (2) connected to the imaging device (4). 11- The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by containing a receiver component (2) that receives the circuit power from the network connected to the power input (13). 12- The claim is related to the wireless imaging electrode system mentioned and its feature is; It is characterized by containing a receiving component (2) that is connected to the imaging device (4) via the device input (14).10