이 페이지는 자동 번역되었으며 번역의 정확성을 보장하지 않습니다. 참조하십시오 영문판 원본 텍스트의 경우.

PRecision Integrated Saturation Monitor (PRISM)

2026년 6월 30일 업데이트: Danielle Gottlieb Sen, Le Bonheur Children's Hospital

PRISM: PRecision Integrated Saturation Monitor A Novel Approach to Monitoring Oxygen Saturation in Children A Prospective, Observational, Comparative Validation Clinical Study to Evaluate the Accuracy of a Novel Abdominal Pulse Oximeter With Integrated Motion Detection and Skin Tone Calibration Against Arterial Blood Gas (SaO₂) Measurements and Conventional Fingertip Pulse Oximetry (SpO₂) in Pediatric Patients.

The purpose of this study is to find out if an abdominal pulse oximeter device is as accurate as a conventional fingertip pulse oximeter in pediatric patients. In this study, we will be collecting data from your medical record while you are being treated in the hospital for your clinical care. Your baby will be in the study for 3 days. There will be no additional study visits. We will collect information already being obtained while your baby is at the hospital.

연구 개요

상세 설명

Conventional pulse oximeters are prone to motion artifacts due to their placement on high-activity limbs. Traditionally, inpatient pulse oximetry relies on clinical staff to verify the accuracy of readings and distinguish between real and false desaturation events. However, in outpatient environments, caregivers are left to manage and interpret signals that may not provide reliable information about their child's health. PRISM aims to improve pulse oximetry monitoring for children. We will test an innovative pulse oximeter prototype that mitigates motion artifacts by shifting the monitoring location from a high-activity limb to the abdomen while incorporating motion detection capabilities. Previously, we have successfully developed an abdomen-worn prototype for collection of ECG signals for infant monitoring (Figure 1). We obtained high-quality signals with a robust correlation to the gold-standard ECG. Our preliminary results demonstrate the feasibility of collecting physiological signals from the abdomen, supporting its use as a novel, baby-friendly monitoring site. Figure 1. Comparison of ECG signals between gold-standard chest ECG and abdomen ECG. Protocol Version 2: 11 June 2026 IRB NUMBER: STUDY00000178 IRB APPROVAL DATE: 6/29/2026 IRB EXPIRATION DATE: 6/2/2027 We will incorporate a commercially available pulse oximetry sensor into a biocompatible, flexible, 3D printed housing. The child-focused design will be specific for application to the abdomen and will clip onto the diaper or pants of the baby; the tension from the diaper or pants will provide ample force to ensure sufficient contact between the device and the skin to achieve robust signals (Figure 2). The device will be removed with each diaper change. Figure 2. Schematic demonstrating the proposed pulse oximeter and its abdominal application As pulse oximetry uses optical sensors, external factors such as ambient light may interfere with data acquisition. Additionally, maintaining reliable contact with the skin is crucial to ensure the emitted light penetrates the underlying tissue, rather than reflecting off the skin's surface. Here, we will design the sensor housing to shield the pulse oximetry sensors from ambient light and provide a contact surface flexible enough for direct skin-to-sensor contact. The PRISM prototype is intended to minimize the impact of motion artifacts, a common phenomenon that leads to inaccurate readings and unnecessary alarms. By shifting the monitoring location from high-activity limbs to the more stable abdomen, we aim to enhance the accuracy and reliability of the device's measurements compared to traditional pulse oximeters. This design choice is particularly relevant for infants and young children, who often experience restlessness and movement during routine monitoring.

Successful accomplishment of this will result in a working prototype with motion artifact-resistant SpO2 reading error of less than 3.0% RMSE from SaO2. This development will allow the caregiver to continuously monitor accurate oxygen status Hypoxemic conditions, or medical problems stemming from low oxygen saturation, can result in half a million deaths annually. Oxygen saturation levels, which determine hypoxic conditions, can be measured directly from arterial blood. This is the gold standard of oxygen saturation measurement and is often called SaO2. Oxygen saturation measured from pulse oximetry, referred to as SpO2, uses light transmission and can allow for early detection of hypoxic conditions. It's a popular belief that melanin can absorb light in pulse oximetry, leading to the overestimation of SpO2 in darker skin. Although individuals with darker skin are observed to have a SpO2 overestimation, clinicians have yet to devise a method to accurately predict oxygen saturation given this overestimation[1]. Various clinical data has been curated to specifically address the issue of biases and disparities of pulse oximeter measurements in darker skin tones including the MIT Critical Datathon 2023 utilizing MIMIC IV and the blood-gas and oximetry linked dataset (BOLD)[2]. One issue with these datasets is race is often used as a proxy for skin tone, but there is great variability in skin color, even within a single race. Without an algorithm to account for how variation in skin tone biases in SpO2 measurement, a disproportionate amount of people of color may continue to receive incorrect diagnoses, leading to health inequities.

These incorrect diagnoses can lead to hidden hypoxemia, which is a condition where the gold standard oxygen saturation of a patient is less than 88% while the pulse oximeter measurement reads over 88%5. Studies show a significant disparity with black patients experiencing nearly three times the frequency of undetected hypoxemia compared to white patients6. They also emphasize the need to integrate pulse oximetry data with other clinical and patient-reported information to address this bias in medical technology.

These results are expected to generate evidence for proof-of-concept for this advanced next-generation pulse oximetry to be further tested and commercialized.

연구 유형

관찰

등록 (추정된)

100

연락처 및 위치

이 섹션에서는 연구를 수행하는 사람들의 연락처 정보와 이 연구가 수행되는 장소에 대한 정보를 제공합니다.

연구 장소

    • Tennessee
      • Memphis, Tennessee, 미국, 38105
        • 모병
        • Le Bonheur Children's Hospital
        • 연락하다:

참여기준

연구원은 적격성 기준이라는 특정 설명에 맞는 사람을 찾습니다. 이러한 기준의 몇 가지 예는 개인의 일반적인 건강 상태 또는 이전 치료입니다.

자격 기준

공부할 수 있는 나이

  • 어린이

건강한 자원 봉사자를 받아들입니다

아니

샘플링 방법

비확률 샘플

연구 인구

Eligible infants hospitalized in the intensive care unit (PICU, PCVICU,NICU) who have already had an arterial line placed and on continuous pulse oximetry monitoring will be considered for enrollment and will be identified and approached for participation during their admission.

설명

Inclusion Criteria:

  • 0-12 months of age. (Must be less than 1 year of life for the pulse oximeter portion of the study) Weight greater than 2 Kg at time of study
  • Admitted to an intensive care unit. (Not applicable for outpatient cohort)
  • Arterial line in place as standard of care (Not applicable for outpatient cohort)
  • Informed consent provided by parent or LAR.

Exclusion Criteria:

  • Open Sternum
  • Skin abnormalities at the proposed sensor site (e.g., rash, eczema, wounds, stoma, or infection)
  • Known allergy or sensitivity to adhesives or materials used in the sensor
  • Excessive movement or irritability that precludes safe and effective placement of the sensor
  • Parent or legal guardian unable to provide informed consent

공부 계획

이 섹션에서는 연구 설계 방법과 연구가 측정하는 내용을 포함하여 연구 계획에 대한 세부 정보를 제공합니다.

연구는 어떻게 설계됩니까?

디자인 세부사항

연구는 무엇을 측정합니까?

주요 결과 측정

결과 측정
측정값 설명
기간
Abdominal SpO2 versus SaO2
기간: From enrollment to end of study at 72 hours.
The primary outcome is the accuracy of abdominal SpO₂ versus SaO₂, measured as root mean square error (RMSE); target ≤ 3.0% RMSE.
From enrollment to end of study at 72 hours.

공동 작업자 및 조사자

여기에서 이 연구와 관련된 사람과 조직을 찾을 수 있습니다.

연구 기록 날짜

이 날짜는 ClinicalTrials.gov에 대한 연구 기록 및 요약 결과 제출의 진행 상황을 추적합니다. 연구 기록 및 보고된 결과는 공개 웹사이트에 게시되기 전에 특정 품질 관리 기준을 충족하는지 확인하기 위해 국립 의학 도서관(NLM)에서 검토합니다.

연구 주요 날짜

연구 시작 (추정된)

2026년 8월 1일

기본 완료 (추정된)

2028년 8월 1일

연구 완료 (추정된)

2028년 12월 1일

연구 등록 날짜

최초 제출

2026년 6월 30일

QC 기준을 충족하는 최초 제출

2026년 6월 30일

처음 게시됨 (실제)

2026년 7월 7일

연구 기록 업데이트

마지막 업데이트 게시됨 (실제)

2026년 7월 7일

QC 기준을 충족하는 마지막 업데이트 제출

2026년 6월 30일

마지막으로 확인됨

2026년 6월 1일

추가 정보

이 연구와 관련된 용어

약물 및 장치 정보, 연구 문서

미국 FDA 규제 의약품 연구

아니

미국 FDA 규제 기기 제품 연구

아니

이 정보는 변경 없이 clinicaltrials.gov 웹사이트에서 직접 가져온 것입니다. 귀하의 연구 세부 정보를 변경, 제거 또는 업데이트하도록 요청하는 경우 register@clinicaltrials.gov. 문의하십시오. 변경 사항이 clinicaltrials.gov에 구현되는 즉시 저희 웹사이트에도 자동으로 업데이트됩니다. .

vital sign monitoring에 대한 임상 시험

3
구독하다