Design, Testing and Evaluation of The Thermobed Device For The Prevention of Brain Damage Due To Neonatal Asphyxia.
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Date
2023-06-16Author
Kato, Hussein Wabbi
Kule, Mujungu
Gawoma, Alice Mercy
Oketayot, Emmanuel
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Show full item recordAbstract
Neonatal asphyxia is a significant cause of neonatal brain injury, morbidity, and mortality
worldwide, often resulting in multi-organ dysfunction and neurological impairment. Cooling
therapy is a widely accepted intervention to mitigate the harmful effects of neonatal asphyxia.
However, existing cooling devices used in healthcare facilities lack an integrated rewarming
function, necessitating the use of separate devices for rewarming after therapy. This creates an
additional burden on both the healthcare system and infant families. The objective of this project
was to design and develop a cost-effective and efficient total body cooling and rewarming device to
address this issue. Our innovative design incorporates two Peltier devices and various other
components. The system is designed to decrease the infant's core body temperature to 33.5 °C and
maintain it for 72 hours. Temperature regulation is achieved through feedback from body and
mattress temperature sensors. Once the cooling therapy is completed, the system gradually rewarms
the mattress, raising the neonate's temperature to 36.5–37 °C. Throughout the process, continuous
monitoring of the infant's body temperature and mattress temperature is enabled. The prototype was
constructed using locally available materials and underwent thorough testing and iterative
refinement to ensure its effectiveness in achieving the desired objective. Accuracy and usability
were evaluated, resulting in an impressive temperature sensor measurement accuracy of 93.2%.
Notably, the prototype was developed at a component cost of less than 100 USD, making it an
affordable solution. Our proposed device enables continuous monitoring of the infant's body
temperature and mattress temperature, eliminating the need for separate rewarming devices. This
breakthrough has the potential to revolutionize neonatal care by streamlining the cooling and
rewarming process and reducing the strain on healthcare systems and families. Future steps include
further development and clinical validation to assess the device's impact on improving outcomes in
neonatal asphyxia cases. The integration of this device into standard care protocols could
significantly enhance neonatal care practices and ultimately save lives.