ISDS Annual Conference Proceedings 2018. This is an Open Access article distributed under the terms of the Creative Commons Attribution-
Noncommercial 3.0 Unported License (http://creativecommons.org/licenses/by-nc/3.0/), permitting all non-commercial use, distribution,  
and reproduction in any medium, provided the original work is properly cited.

ISDS 2018 Conference Abstracts

Developing and Deploying Universal Diagnostic 
Platforms for One-Health Biosurveillance
Harshini Mukundan*
Chemistry, Los ALamos National Laboratory, Los ALamos, NM, USA

Objective
Our goal is to develop deployable strategies for infectious disease 

diagnosis at the point-of-care that are applicable to multiple hosts 
of infection - conforming to the global One Health Strategy for 
diagnostics. We aim to develop methods that do not require prior 
knowledge of the pathogen in question, and can facilitate rapid and 
effective decision-making and situational awareness.

Introduction
There is an urgent need for diagnostic strategies for infections 

which are host-independent, so as to effectively track zoonotic spread, 
monitor animal carriers of pathogens, and evaluate transmission 
dynamics. Infection of a host - pathogen or human- by an animal 
results in recognition by the immune response, which consequently 
causes release of inflammatory mediators. Many scientists have 
explored the use of cytokines as diagnostic indicators of disease, 
but the conserved nature of the immune response in humans and 
animals results in cross-reactivity among many pathogens, making 
evaluation of the results difficult, especially in high disease burden 
populations. Measuring the pathogen-specific signature, however, is 
advantageous - as it offers discrete identification of active infection, 
and discrimination from exposure. It also offers a universal strategy 
that can be applied to human and animal hosts of infection - allowing 
for One Health Biosurveillance. Achieving this, however, requires 
the development of a) tailored strategies for the measurement of 
biochemically disparate pathogen signatures in clinical samples and 
b) ultra-sensitive detection of such signatures in the host. The sensor
team at Los Alamos National Laboratory is working on both of these
aspects, and the development of One Health Diagnostic platforms, the
focus of the work presented here.

Methods
Many of the biomarkers secreted by bacterial pathogens and 

recognized by innate immune receptors elicit host cytokine responses 
that are amphiphilic (largely glycolipids, lipoproteins or lipoglycans). 
Based on such, our team has developed tailored methods – membrane 
insertion and lipoprotein capture for the capture and detection of 
these greasy and stealthy molecules in infected blood. Sensitivity 
and specificity, assay optimization, alinearity associated with lipidic 
molecules and assay parameter development for biomarkers associated 
with bacterial pathogens will be presented. Considerations for clinical 
sampling for amphiphile detection in blood, and clinical study design 
will be demonstrated. Our team has developed an ultra-sensitive 
biosensor for detection of biomarkers in complex matrices based on the 
evanescent field properties of single mode planar optical waveguides. 
Detection of amphiphilic biomarkers in clinical samples, using the 
waveguide-based biosensor and tailored methods for the detection 
of such molecules has allowed for the diagnosis of infection in both 
human and animals hosts. Herein, we present two examples of the 
same; 1) diagnosis of tuberculosis in humans, cattle and badgers using 
pathogen-based diagnostic strategies; and 2) detection of Gram-negative 
Lipopolysacharides in beef and in patients with Salmonella-induced sepsis.

Results
We have developed tailored ultra-sensitive waveguide-biosensor 

assays for the detection of Lipoarabinomannan (and other biomarkers) 

from Mycobacteria and demonstrated feasibility in blinded clinical 
studies in humans and cattle, demonstrating one -health compatibility. 
We have also demonstrated detection of lipopolysacharides from 
eight different serotypes of Shiga-toxin carrying E. coli in beef, and 
Salmonella Typhimurium in pediatric patients using the same approach.

Conclusions
We have demonstrated clinical feasibility of a One Health Strategy 

for point-of-care diagnostics of bacterial infections in blood for 
tuberculosis and Gram-negative pathogens in clinical samples. 
The results will be demonstrated with several discussion points on 
the consideration of unconventional biochemistry of pathogens 
for diagnostics, factors influencing point-of-care deployment and 
integration of diagnostic platforms for biosurveillance. One Health 
Considerations and challenges therein will also merit discussion

Keywords
universal diagnostics; one health; deployable sensors

Acknowledgments
UBS concept and the Gram-positive and Gram-negative assay 
development was supported by Los Alamos National Laboratory Directed 
Research Award to McMahon and Mukundan. The Lipopolysacharide 
assay for cattle was supported by USDA (Mukundan). The Tuberculosis 
Diagnostics work was supported by NIH R21 (Dorman, JHU with 
Mukundan, LANL Lead). We thank several people at LANL, UNM, 
JHU for technical and administrative support. we thank the patients who 
generously contributed samples to our effort from Uganda, Kenya and 
South Korea.

References
Sakamuri, R; et al. Accurate Tracking of Bovine Tuberculosis Biomarkers 

in Infected Cattle using a Novel Biomarker Capture Strategy, 
Analytical Sciences, 33(4): 457-460, 2017.

Noormohammed A et al. Detection of Salmonella LPS in Patient blood 
by Lipoprotein Capture. Proc. SPIE 10072, Optical Diagnostics and 
Sensing XVII: Toward Point-of-Care Diagnostics, 100720A, 2017. 
doi:10.1117/12.2253506

Stromberg L et al. Membrane Insertion for the Detection of 
Lipopolysaccharides: Exploring the Dynamics of Amphiphile-in-
Lipid Assays, PloS One, April 2016.

Sakamuri RM et al. Association of lipoarabinomannan with high density 
lipoprotein in blood: implications for diagnostics. Tuberculosis 
(Edinb). 2013 May;93(3):301-7. doi: 10.1016/j.tube.2013.02.015. 
Epub 2013 Mar 16

Mukundan H et al. Understanding the interaction of Lipoarabinomannan 
with membrane mimetic architectures. Tuberculosis, 92(1) 32-47, 2012.

Mukundan H et al., Waveguide-based Sensors for Pathogen Detection, 
Invited Review, Sensors, 9(7), 5783-5809.

*Harshini Mukundan
E-mail: HARSHINI@LANL.GOV

Online Journal of Public Health Informatics * ISSN 1947-2579 * http://ojphi.org * 10(1):e107, 2018