What question did this study set out to answer?

To develop an IoT-based system for continuous tracking of physiological parameters for remote healthcare.

April 1, 2026Open Access

IoTBased RealTime Health Monitoring Framework for Remote Healthcare

Q: What is the clinical evidence from this study?

Study design: Other. Population: Remote Healthcare Monitoring. Intervention: IoT-Based Real-Time Health Monitoring Framework. Primary outcome: System latency and connectivity.

Q: What does this research mean for the field?

An IoT-based health monitoring framework utilizing a NodeMCU microcontroller successfully captures and securely transmits real-time physiological parameters to a cloud platform with minimal latency and stable connectivity. Novelty: ClaimNovelty.METHODOLOGICAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

Key Result

The IoT-based health monitoring framework successfully captured and transmitted real-time physiological parameters to a cloud platform with minimal latency and stable connectivity.

Key Points

To develop an IoT-based system for continuous tracking of physiological parameters for remote healthcare.
Developed a monitoring system using NodeMCU microcontroller
Utilized sensors to track core body temperature, pulse rate, and SpO2 levels
Transmitted data to Adafruit IO cloud platform using Wi-Fi
Ensured secure transmission of health data via IoT technology
Achieved reliable real-time monitoring of critical health parameters
Demonstrated low-cost and portable health monitoring solution
Indicated potential for integration with artificial intelligence for predictive health insights

Structured PICO

Intervention

IoT-based real-time health monitoring framework using NodeMCU (ESP8266) microcontroller, DHT11 sensor, and MAX30100 sensor with Adafruit IO cloud integration

Outcome

レイテンシ、接続性、およびユーザーインターフェース機能を含むシステムのパフォーマンス

The proposed IoT-based framework provides a low-cost, portable, and reliable solution for real-time remote monitoring of vital signs.

Limitations

Lack of mobile application support
Absence of artificial intelligence for health prediction
Lack of instant alert mechanisms for emergencies
Not yet integrated with wearable devices
Requires wider scale deployment to ensure uniform services

Abstract

Present-day healthcare mandates a shift from reactive to proactive monitoring. This paper proposes a strong IoT-driven architecture designed for the continuous tracking of critical physiological parameters, including core body temperature, pulse rate, and peripheral oxygen saturation (SpO2). By use of a NodeMCU (ESP8266) microcontroller, the system digitizes analog sensor data and organize its transmission to the Adafruit IO cloud platform via Wi-Fi. We aim to provide a low-cost,portable,and highly accurate remote monitor that shows real-time patient data to doctors. The system maintain secure transmission of health data and can be further improved by incorporating advanced technologies like artificial intelligent for predicting potential health issues.

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Cite This Study

クマールら（Sun,）は、遠隔医療モニタリングにおいて別の研究を行いました。IoTベースのリアルタイム健康モニタリングフレームワークは、システムのレイテンシと接続性において評価されました。このIoTベースの健康モニタリングフレームワークは、最小限のレイテンシと安定した接続性でリアルタイムの生理学的パラメータをクラウドプラットフォームに成功裏にキャプチャし、送信しました。

synapsesocial.com/papers/69ccb6e416edfba7beb88a01 https://doi.org/https://doi.org/10.56975/ijedr.v14i1.305364

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