Saved in:
Bibliographic Details
Main Authors: Bhattacharjee, Sunasheer, Bi, Dadi, Hofmann, Pit, Wietfeld, Alexander, Becke, Sophie, Lommel, Michael, Zhou, Pengjie, Zheng, Ruifeng, Kertzscher, Ulrich, Deng, Yansha, Kellerer, Wolfgang, Fitzek, Frank H. P., Dressler, Falko
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.18326
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913807580790784
author Bhattacharjee, Sunasheer
Bi, Dadi
Hofmann, Pit
Wietfeld, Alexander
Becke, Sophie
Lommel, Michael
Zhou, Pengjie
Zheng, Ruifeng
Kertzscher, Ulrich
Deng, Yansha
Kellerer, Wolfgang
Fitzek, Frank H. P.
Dressler, Falko
author_facet Bhattacharjee, Sunasheer
Bi, Dadi
Hofmann, Pit
Wietfeld, Alexander
Becke, Sophie
Lommel, Michael
Zhou, Pengjie
Zheng, Ruifeng
Kertzscher, Ulrich
Deng, Yansha
Kellerer, Wolfgang
Fitzek, Frank H. P.
Dressler, Falko
contents Molecular Communication (MC) has long been envisioned to enable an Internet of Bio-Nano Things (IoBNT) with medical applications, where nanomachines within the human body conduct monitoring, diagnosis, and therapy at micro- and nanoscale levels. MC involves information transfer via molecules and is supported by well-established theoretical models. However, practically achieving reliable, energy-efficient, and bio-compatible communication at these scales still remains a challenge. Air-Based Molecular Communication (ABMC) is a type of MC that operates over larger, meter-scale distances and extends even outside the human body. Therefore, devices and techniques to realize ABMC are readily accessible, and associated use cases can be very promising in the near future. Exhaled breath analysis has previously been proposed. It provides a non-invasive approach for health monitoring, leveraging existing commercial sensor technologies and reducing deployment barriers. The breath contains a diverse range of molecules and particles that serve as biomarkers linked to various physiological and pathological conditions. The plethora of proven methods, models, and optimization approaches in MC enable macroscale breath analysis, treating human as the transmitter, the breath as the information carrier, and macroscale sensors as the receiver. Using ABMC to interface with the inherent dynamic networks of cells, tissues, and organs could create a novel Internet of Bio Things (IoBT), a preliminary macroscale stage of the IoBNT. This survey extensively reviews exhaled breath modeling and analysis through the lens of MC, offering insights into theoretical frameworks and practical implementations from ABMC, bringing the IoBT a step closer to real-world use.
format Preprint
id arxiv_https___arxiv_org_abs_2504_18326
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Exhaled Breath Analysis Through the Lens of Molecular Communication: A Survey
Bhattacharjee, Sunasheer
Bi, Dadi
Hofmann, Pit
Wietfeld, Alexander
Becke, Sophie
Lommel, Michael
Zhou, Pengjie
Zheng, Ruifeng
Kertzscher, Ulrich
Deng, Yansha
Kellerer, Wolfgang
Fitzek, Frank H. P.
Dressler, Falko
Emerging Technologies
Molecular Communication (MC) has long been envisioned to enable an Internet of Bio-Nano Things (IoBNT) with medical applications, where nanomachines within the human body conduct monitoring, diagnosis, and therapy at micro- and nanoscale levels. MC involves information transfer via molecules and is supported by well-established theoretical models. However, practically achieving reliable, energy-efficient, and bio-compatible communication at these scales still remains a challenge. Air-Based Molecular Communication (ABMC) is a type of MC that operates over larger, meter-scale distances and extends even outside the human body. Therefore, devices and techniques to realize ABMC are readily accessible, and associated use cases can be very promising in the near future. Exhaled breath analysis has previously been proposed. It provides a non-invasive approach for health monitoring, leveraging existing commercial sensor technologies and reducing deployment barriers. The breath contains a diverse range of molecules and particles that serve as biomarkers linked to various physiological and pathological conditions. The plethora of proven methods, models, and optimization approaches in MC enable macroscale breath analysis, treating human as the transmitter, the breath as the information carrier, and macroscale sensors as the receiver. Using ABMC to interface with the inherent dynamic networks of cells, tissues, and organs could create a novel Internet of Bio Things (IoBT), a preliminary macroscale stage of the IoBNT. This survey extensively reviews exhaled breath modeling and analysis through the lens of MC, offering insights into theoretical frameworks and practical implementations from ABMC, bringing the IoBT a step closer to real-world use.
title Exhaled Breath Analysis Through the Lens of Molecular Communication: A Survey
topic Emerging Technologies
url https://arxiv.org/abs/2504.18326