Anesthesia Equipment Monitor Solution Based on i.MX 6ULL SOM by MYIR

With the rapid advancements in medical sensor and electronic technologies, patient monitoring techniques have significantly progressed. The continuous escalation in the monitoring of various physiological parameters has led to the emergence of anesthesia depth monitoring in recent years. This device is utilized to quantify the hypnotic state of patients during anesthesia, ensuring enhanced protection of their life safety by monitoring the hypnotic state of the patient's brain while anesthetics and other medications are administered. Anesthesia machines not only alleviate patients' surgical pain and improve their cooperation during the procedure but also provide oxygen supply and respiratory assistance, ensuring the normal functioning of the patient's body.

The anesthesia machine primarily comprises a gas supply unit, an evaporator, a respiratory circuit, a carbon dioxide absorption unit, an anesthesia ventilator, a monitoring and alarm system, and an anesthesia waste gas elimination system. Proper anesthesia ensures patients experience no pain during surgery, whereas improper anesthesia can lead to various issues and even jeopardize the patient's life and health. Consequently, anesthesiologists prioritize controlling the concentration of anesthetic agents and monitoring vital signs such as respiration and blood oxygen levels. The anesthesia machine's monitoring and alarm system utilizes various sensors to accurately track parameters like anesthetic flow, oxygen concentration, airway pressure, and respiratory cycle. It triggers an alarm when abnormal conditions arise, such as high or low airway pressure, abnormal ventilation volume, or prolonged inhalation time.

MYIR's MYC-Y6ULX-V2 System-On-Module (SOM), based on NXP's i.MX 6UL/6ULL ARM Cortex-A7 processors, can be utilized in anesthesia equipment monitoring systems. This module effectively monitors and regulates the administration of anesthetic drugs to patients, gathers equipment parameters, and aids anesthesiologists in precisely assessing anesthesia status. With ample storage capacity, it supports historical data storage and querying. It boasts rich serial port resources, capable of accommodating various gas sensors in anesthesia equipment. Additionally, it supports 3G/4G wireless transmission networks for data collection and uploading. Connectivity with high-definition touchscreen displays is enabled, visualizing anesthesia drug usage monitoring during surgery via a user-friendly human-machine interface. Industrial-grade, high-quality electronic components can be selected to meet the electrical characteristics and electromagnetic compatibility requirements of medical products. The Linux operating system facilitates straightforward secondary development, expediting the launch of medical products.