A biocompatible microdevice for core body temperature monitoring in the early diagnosis of infectious disease

Williamson, E. Diane; Savage, Victoria L.; Lingard, Bry; Russell, Paul F.; Scott, Elizabeth

doi:10.1007/s10544-006-9007-5

Cited by 16 publications

(11 citation statements)

References 22 publications

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“…A deviation from this diurnal Tc pattern was the first indication of infection with F. tularensis, with the appearance of overt clinical signs, particularly piloerection, at 12-18 h later. Temperature increases followed by clinical signs have been reported previously in murine studies (Williamson et al 2007). In the present study, a longer delay between temperature increase and the onset of clinical signs was observed.…”

Section: Discussionsupporting

confidence: 74%

Establishment of lethal inhalational infection with Francisella tularensis (tularaemia) in the common marmoset (Callithrix jacchus)

Nelson

Lever

Savage

et al. 2009

Int J Experimental Path

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Susceptibility and lethality studies of inhalational tularaemia were undertaken using the common marmoset (Callithrix jacchus) to determine its suitability as a non-human primate model. Pairs of marmosets were exposed to varying challenge doses of Francisella tularensis by the airborne route and monitored for up to 14 days postchallenge (p.c.). Lethal infection was achieved following a retained dose of less than 10 bacterial colony-forming units (CFU). However, precise LD(50) determination was not possible. The model was characterized using a target challenge dose of approximately 100 CFU. Increased core body temperature was the first indicator of disease, at approximately 2.5 days p.c. Overt clinical signs were first observed 12-18 h after the temperature increase. Significantly decreased activity was observed after approximately 3 days. All animals succumbed to infection between 4.5 and 7 days p.c. At postmortem examination, gross pathology was evident in the liver, spleen and lungs of all animals and high bacterial numbers were detected in all the organs assessed. Bacteraemia was demonstrated in all animals postmortem. Histopathological observations included severe suppurative bronchopneumonia, severe multifocal pyogranulomatous hepatitis, splenitis and lymphadenitis. Tularaemia disease progression in the common marmoset therefore appears to be consistent with the disease seen in humans and other animal models. The common marmoset may therefore be considered a suitable model for further studies of inhalational tularaemia.

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Section: Discussionsupporting

confidence: 74%

Establishment of lethal inhalational infection with Francisella tularensis (tularaemia) in the common marmoset (Callithrix jacchus)

Nelson

Lever

Savage

et al. 2009

Int J Experimental Path

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“…Previous work on physiological signal-based early infection detection work has been heavily focused on systemic bacterial infection ( Korach et al, 2001 ; Chen and Kuo, 2007 ; Ahmad et al, 2009 ; Papaioannou et al, 2012 ; Scheff et al, 2012 , 2013b ), and largely centered upon higher sampling rates of body core temperature ( Williamson et al, 2007 ; Papaioannou et al, 2012 ), advanced analyses of strongly-confounded signals such as heart rate variability ( Korach et al, 2001 ; Chen and Kuo, 2007 ; Ahmad et al, 2009 ) or social dynamics ( Madan et al, 2010 ), or sensor data fusion from already symptomatic (febrile) individuals ( Sun et al, 2013 ). While great progress has been made in developing techniques for physiological-signal based early warning of bacterial infections and other critical illnesses in a hospital setting ( Heldt et al, 2006 ; Liu et al, 2011 , 2014a ; Lehman et al, 2014 ), efforts to extend these techniques to viral infections or other communicable pathogens in non-clinical contexts using wearable sensor systems have only recently been pursued in observational studies on human subjects, primarily as a rapid response to the COVID-19 pandemic ( Li et al, 2017 ; Miller et al, 2020 ; Mishra et al, 2020 ; Natarajan et al, 2020 ; Quer et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Detecting Pathogen Exposure During the Non-symptomatic Incubation Period Using Physiological Data: Proof of Concept in Non-human Primates

et al. 2021

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Background and Objectives: Early warning of bacterial and viral infection, prior to the development of overt clinical symptoms, allows not only for improved patient care and outcomes but also enables faster implementation of public health measures (patient isolation and contact tracing). Our primary objectives in this effort are 3-fold. First, we seek to determine the upper limits of early warning detection through physiological measurements. Second, we investigate whether the detected physiological response is specific to the pathogen. Third, we explore the feasibility of extending early warning detection with wearable devices.Research Methods: For the first objective, we developed a supervised random forest algorithm to detect pathogen exposure in the asymptomatic period prior to overt symptoms (fever). We used high-resolution physiological telemetry data (aortic blood pressure, intrathoracic pressure, electrocardiograms, and core temperature) from non-human primate animal models exposed to two viral pathogens: Ebola and Marburg (N = 20). Second, to determine reusability across different pathogens, we evaluated our algorithm against three independent physiological datasets from non-human primate models (N = 13) exposed to three different pathogens: Lassa and Nipah viruses and Y. pestis. For the third objective, we evaluated performance degradation when the algorithm was restricted to features derived from electrocardiogram (ECG) waveforms to emulate data from a non-invasive wearable device.Results: First, our cross-validated random forest classifier provides a mean early warning of 51 ± 12 h, with an area under the receiver-operating characteristic curve (AUC) of 0.93 ± 0.01. Second, our algorithm achieved comparable performance when applied to datasets from different pathogen exposures – a mean early warning of 51 ± 14 h and AUC of 0.95 ± 0.01. Last, with a degraded feature set derived solely from ECG, we observed minimal degradation – a mean early warning of 46 ± 14 h and AUC of 0.91 ± 0.001.Conclusion: Under controlled experimental conditions, physiological measurements can provide over 2 days of early warning with high AUC. Deviations in physiological signals following exposure to a pathogen are due to the underlying host’s immunological response and are not specific to the pathogen. Pre-symptomatic detection is strong even when features are limited to ECG-derivatives, suggesting that this approach may translate to non-invasive wearable devices.

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“…Furthermore, molecular diagnostics are rarely used until patient self-reporting and presentation of overt clinical symptoms, such as fever. Past physiological signal-based early infection detection work has been heavily focused on systemic bacterial infection [30][31][32][33][34][35], and largely centered upon higher sampling rates of body core temperature [35,36], advanced analyses of stronglyconfounded signals such as heart rate variability [31][32][33] or social dynamics [37], or sensor data fusion from already symptomatic (febrile) individuals [38]. While great progress has been made in developing techniques for signal-based early warning of bacterial infections and other critical illnesses in a hospital setting [39][40][41][42], we are aware of only one prior effort to extend these techniques to viral infections or other communicable pathogens in non-clinical contexts using wearable sensor systems [43].…”

Section: Introductionmentioning

confidence: 99%

Detecting pathogen exposure during the non-symptomatic incubation period using physiological data

Milechin

Davis

Patel

et al. 2017

Preprint

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Early pathogen exposure detection allows better patient care and faster implementation of public health measures (patient isolation, contact tracing). Existing exposure detection most frequently relies on overt clinical symptoms, namely fever, during the infectious prodromal period. We have developed a robust machine learning based method to better detect asymptomatic states during the incubation period using subtle, sub-clinical physiological markers. Starting with highresolution physiological waveform data from non-human primate studies of viral (Ebola, Marburg, Lassa, and Nipah viruses) and bacterial (Y. pestis) exposure, we processed the data to reduce short-term variability and normalize diurnal variations, then provided these to a supervised random forest classification algorithm and post-classifier declaration logic step to reduce false alarms. In most subjects detection is achieved well before the onset of fever; subject cross-validation across exposure studies (varying viruses, exposure routes, animal species, and target dose) lead to 51h mean early detection (at 0.93 area under the receiver-operating characteristic curve [AUCROC]). Evaluating the algorithm against entirely independent datasets for Lassa, Nipah, and Y. pestis exposures un-used in algorithm training and development yields a mean 51h early warning time (at AUCROC=0.95). We discuss which physiological indicators are most informative for early detection and options for extending this capability to limited datasets such as those available from wearable, non-invasive, ECG-based sensors.

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A biocompatible microdevice for core body temperature monitoring in the early diagnosis of infectious disease

Cited by 16 publications

References 22 publications

Establishment of lethal inhalational infection with Francisella tularensis (tularaemia) in the common marmoset (Callithrix jacchus)

Establishment of lethal inhalational infection with Francisella tularensis (tularaemia) in the common marmoset (Callithrix jacchus)

Detecting Pathogen Exposure During the Non-symptomatic Incubation Period Using Physiological Data: Proof of Concept in Non-human Primates

Detecting pathogen exposure during the non-symptomatic incubation period using physiological data

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