RU212590U1 - TRANSMITTER FOR AUTOMATIC INSULIN DISPENSER IN ARTIFICIAL PANCREATIS SYSTEM MODIFIED - Google Patents

Abstract

The utility model relates to medicine, namely to medical devices for creating an artificial pancreas system, and can be used as a modified transmitter for an automatic insulin dispenser in an artificial pancreas system that communicates the algorithm of the artificial pancreas system and the insulin dispenser. For this purpose, a modified transmitter for an automatic insulin dispenser, including a Bluetooth module, a radio module, a band-pass filter, an antenna, a lithium polymer battery, a battery pack connector, a USB block, a switch, debug pads, LEDs, uses a 650 mA lithium polymer battery /H and a 433 MHz antenna. The utility model expands the arsenal of tools available for a wide range of patients with type 1 diabetes, allows you to connect to insulin pumps from Medtronic and Omnipod, and eliminates shielding of the transmitted signal when installed in the housing.

Description

The utility model relates to medicine, namely to medical devices for creating an artificial pancreas system, and can be used as a modified transmitter for an automatic insulin dispenser in an artificial pancreas system that communicates the algorithm of the artificial pancreas system and the insulin dispenser.

Currently, the artificial pancreas system consists of three components: a sensor for continuous glucose monitoring, an insulin pump (insulin dispenser) and a computer algorithm that synchronizes the operation of the sensor and the pump (https://rule15s.com/knowledge/iskusstvennaya-podzheludochnaya-zheleza -sistema-zakrytoy-loops).

Dosers are known with the ability to automatically change the rate of insulin delivery according to glucose monitoring (an insulin pump with built-in glucose monitoring that predicts blood sugar levels automatically changes the rate of insulin delivery). Not registered in the Russian Federation, registered in Europe in June 2020. https://www.medtronic-diabetes.co.uk/insulin-pump-therapy/minimed-780g-system). This type of dispenser allows the patient to measure the glucose level with a glucometer only once a day (to calibrate the monitor) and tell the insulin pump when and how much he is going to eat carbohydrates.

However, dispensers of this type have not yet been widely used due to their high cost and low availability for patients.

In this regard, there remains a high need to expand the arsenal of tools needed to create affordable artificial pancreas systems (“closed loop” systems).

Known transmitter RileyLink, linking the algorithm with the insulin pump. The device is not used separately from the closed loop system. Has an open license (https://github.com/LoopKit/Loop/blob/master/LICENSE.md). The RileyLink device contains a Blue tooth module, a radio module, a band pass filter, an antenna, a lithium polymer battery, a battery pack connector, a mini USB block, a switch, debug pads, LEDs (https://github.com/ps2/rileylink/blob/ master/hardware/Schematic.pdf)

The disadvantage of the device is the shielding of the antenna during installation, as well as the limited ability of the 868 MHz antenna installed in it to transmit a signal only to the Medtronic insulin pump.

The technical result of the utility model is the elimination of antenna shielding when installed in the housing and the expansion of functionality associated with signal transmission to Medtronic and Omnipod insulin pumps, which makes Riley Link more versatile.

The specified technical result is achieved in a transmitter for an automatic insulin dispenser in an artificial pancreas system, including a Bluetooth module, a radio module, a band-pass filter, an antenna, a lithium-polymer battery, a battery pack connector, a USB block, a switch, contact pads for debugging, LEDs, in which use a lithium-polymer battery 650 mA / N and an antenna 433 MHz.

Replacing the battery from lithium polymer 800 mA/H to lithium polymer 650 mA/H is due to the fact that the described 800 mA/H battery is larger and shields the signal source (antenna) during installation. The 650 mA/Η battery offered by us is smaller in size and does not shield the antenna when installed in the housing.

Unlike the 868 MHz antenna described in the well-known Riley Link device, the 433 MHz antenna in the claimed device can transmit a signal to Medtronic and Omnipod insulin pumps. Thus, Riley Link in the proposed modification becomes universal.

Thus, the differences of the proposed transmitter are presented below in table.

In FIG. - functional block diagram of the transmitter (RileyLink devices);

According to the block diagram, the device contains: module 1 (bluetooth 4.0), radio module 2 (CC1110), band pass filter 3 (at 915 MHz), antenna 4 (433 MHz), battery 5 (lithium polymer 650 mA/Η), battery pack connector 6, mini USB box 7, switch 8, pads 9 for debugging, LED 10 (LED green), LED 11 (LED blue), LED 12 (LED blue RF), LED 13 (LED green RF), LED 14 (LED) red-charge).

The device works as follows.

When information is transmitted from a smartphone to an insulin pump, the digital signal received from a smartphone via a Bluetooth connection via Bluetooth module 1 is transmitted to radio module 2, where it is transformed into an analog radio frequency signal and transmitted through a bandpass filter 3 to antenna 4. Antenna 4 broadcasts an analog radio signal that an insulin pump can accept. When information is transmitted from the insulin pump to a smartphone, the analog radio signal received by antenna 4 is transmitted through a bandpass filter 3 to radio module 2, where it is converted into a digital signal and transmitted to the smartphone via Bluetooth module 1.

The operation of the device is carried out at the expense of the energy of the battery (accumulator) 5, which is connected to the device through connector 6. The battery 5 is recharged via the USB block 7, LED 14 lights up during recharging, and when the charge is completed, the LED goes out. An additional option may be to connect a wireless charging module for the Qi standard. The device is turned on and off using switch 8. Device debugging and software installation is carried out through contact pads for debugging 9. An active Bluetooth connection between the device and the smartphone is indicated by the glow of LED 10. LEDs 11, 12, 13 are diagnostic and are used to debug the device and visualization of components.

The claimed utility model expands the arsenal of tools available for a wide range of patients with type 1 diabetes, allows you to connect to Medtronic and Omnipod insulin pumps, and eliminates the shielding of the transmitted signal when installed in the case.

Claims (1)

A modified transmitter for an automatic insulin dispenser, including a Bluetooth module, a radio module, a band-pass filter, an antenna, a lithium polymer battery, a battery pack connector, a USB block, a switch, debugging pads, LEDs, characterized in that the device uses a lithium polymer battery 650 mA / N and a 433 MHz antenna, and the battery is made to eliminate the shielding of the transmitted signal when installed in the case.

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