# A New Tool to Rapidly Diagnose Sepsis using Flow Imaging Microscopy and Machine Learning

> **NIH NIH R43** · URSA ANALYTICS, INC. · 2020 · $224,803

## Abstract

Project Summary
 Sepsis is a serious condition induced by an infection, often by a bacterial pathogen, leading to organ damage
or even death. Despite numerous advances in medicine over the years, the condition still affects millions of people
in both developed and developing countries. In the US, sepsis affects 1.7M and kills over 265,000 people annually.
Sepsis mortality rates in developing countries are substantially higher. In terms of demographics, sepsis affects
humans of all age and race, but it is most pronounced at the age extremes (infants and the elderly) and patients
whose immune system is already under strain due to other illnesses or immune system-weakening therapies,
e.g., cancer patients undergoing chemotherapy.
 Blood cultures are currently the default technique used in detecting and diagnosing the root cause of sepsis.
However, blood-cultures can take upwards of 24-48 hours in order to obtain results. In that time, the patient
can experience irreversible harm due to the condition if not treated properly. Unfortunately, precise and effective
antibiotic treatment requires knowledge of the pathogen causing sepsis. Beyond a long time to get an answer,
blood cultures often exhibit alarmingly high false negatives (failure to detect a pathogen causing sepsis) and
typically do not precisely identify the pathogen causing sepsis.
 Hence there have been several efforts aimed at detecting and identifying the broad range of potential pathogens
causing sepsis and circumventing the need for blood cultures. However, many of the recently proposed methods
for detecting and diagnosing sepsis exhibit one or more of the following drawbacks: (i) they lack high sensitivity
(ability to detect a pathogen); (ii) they cannot accurately identify a broad range of pathogens from a single sam-
ple; (iii) take a (relatively) long time; (iv) require a large volume of blood; or (v) cannot be used in the real-time
monitoring of sepsis (either detecting pathogens known to cause sepsis or quantifying the patient's response to
antimicrobial treatment).
 We are proposing a new sepsis detection method, combining flow imaging microscopy (a high-throughput
technique for imaging millions of microscopic particles) and deep learning based image analysis (techniques
leveraged in facial recognition and self-driving cars) to overcome the above mentioned limitations. The approach
has proven capable of detecting a variety of bacterial species in low concentrations of mouse blood in less than
1 hour of processing time with as little as 50 L of blood. In this proposal, one of our aims is to optimize our
approach and quantify the accuracy and limits of detection in human blood. Our patent pending approach has
also been licensed to a major manufacturer of flow imaging microscopes. Another aim of this research is to begin
integration of our technology with an existing commercial instrument with the intention of providing a compact self-
contained device that can be deployed at numerous...

## Key facts

- **NIH application ID:** 10078833
- **Project number:** 1R43EB029863-01A1
- **Recipient organization:** URSA ANALYTICS, INC.
- **Principal Investigator:** Christopher Peter Calderon
- **Activity code:** R43 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2020
- **Award amount:** $224,803
- **Award type:** 1
- **Project period:** 2020-09-16 → 2023-09-15

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/10078833

## Citation

> US National Institutes of Health, RePORTER application 10078833, A New Tool to Rapidly Diagnose Sepsis using Flow Imaging Microscopy and Machine Learning (1R43EB029863-01A1). Retrieved via AI Analytics 2026-05-23 from https://api.ai-analytics.org/grant/nih/10078833. Licensed CC0.

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