Background:
In the medical field, temperature is an extremely important physiological parameter. The temperatures of various parts of the human body serve as crucial bases for diagnosing diseases. For instance, the surface body temperature helps in diagnosing shock, an elevated body temperature indicates an infection, anesthesia has an impact on body temperature, incubators require precise temperature control to protect newborns, and joint temperature reflects inflammation. Temperature measurement is of great significance, and the core difference among different measurement methods lies in the choice of temperature.
Measurement Requirements:
In medical research, for a certain medical graduate student’s cell culture, the temperature needs to be maintained between 35°C and 39°C, and the sensor accuracy should reach ±0.1°C or higher. Given the diverse environments, the sensor’s measurement range should cover from tens of degrees below zero Celsius to over a hundred degrees Celsius. It should also be able to adapt to temperature and pressure changes. Moreover, in the face of rapid temperature changes, it must be able to respond quickly. Additionally, for long – term experiments, the sensor should be anti – interference, anti – erosion, stable, and reliable. In the aseptic environment of cell culture, the sensor material should be antibacterial and compatible with the experimental solution.
Solution:
To address the challenge of precise temperature measurement in medical research, the research institute has introduced a new intelligent temperature sensor. This sensor is specifically designed for complex medical research scenarios and has excellent high – temperature resistance, high – pressure resistance, and chemical corrosion resistance. It adopts advanced thermistor technology, which can quickly and accurately detect temperature changes.
This sensor is equipped with an intelligent data processing module that can analyze data in real – time, automatically calibrate, and eliminate errors caused by environmental interferences such as temperature and pressure. Considering the laboratory space and aseptic requirements, it is installed in an immersion – type manner. It can be measured by being put into the container. Its shell is antibacterial and corrosion – resistant, and the cable has good flexibility and corrosion resistance. It is small in size, easy to clean, and can be cleaned and disinfected after the experiment to ensure operation in an aseptic environment. After installation, through the debugging and verification by the scientific research team and the supplier, the accuracy and stability of the measurement results are comprehensively ensured.
Conclusion:
In summary, the new intelligent temperature sensor introduced by this medical research institute not only satisfies the stringent requirements in medical research for temperature measurement in terms of high precision, wide measurement range, rapid response, stability, reliability, and aseptic compatibility. Through practical applications, it has effectively resolved key issues such as abnormal temperature monitoring. This sensor provides robust support for the accuracy and stability of medical research, significantly propelling the development of medical research in areas such as the research, development, and production of innovative drugs.
