Your search keyword '"Civaş, Meltem"' showing total 16 results

1. Frequency-Domain Detection for Molecular Communication with Cross-Reactive Receptors

Author

Civas, Meltem, Kuscu, Murat, and Akan, Ozgur B.

Subjects

Electrical Engineering and Systems Science - Signal Processing, Computer Science - Emerging Technologies

Abstract

Molecular Communications (MC) is a bio-inspired communication paradigm that uses molecules as information carriers, requiring unconventional transceivers and modulation/detection techniques. Practical MC receivers (MC-Rxs) can be implemented using field-effect transistor biosensor (bioFET) architectures, where surface receptors reversibly react with ligands. The time-varying concentration of ligand-bound receptors is translated into electrical signals via field effect, which is used to decode the transmitted information. However, ligand-receptor interactions do not provide an ideal molecular selectivity, as similar ligand types, i.e., interferers, co-existing in the MC channel, can interact with the same type of receptors. Overcoming this molecular cross-talk in the time domain can be challenging, especially when Rx has no knowledge of the interferer statistics or operates near saturation. Therefore, we propose a frequency-domain detection (FDD) technique for bioFET-based MC-Rxs that exploits the difference in binding reaction rates of different ligand types reflected in the power spectrum of the ligand-receptor binding noise. We derive the bit error probability (BEP) of the FDD technique and demonstrate its effectiveness in decoding transmitted concentration signals under stochastic molecular interference compared to a widely used time-domain detection (TDD) technique. We then verified the analytical performance bounds of the FDD through a particle-based spatial stochastic simulator simulating reactions on the MC-Rx in microfluidic channels., Comment: Submitted to the IEEE for possible publication. arXiv admin note: text overlap with arXiv:2301.01049

Published

2023

2. Graphene and Related Materials for the Internet of Bio-Nano Things

Author

Civas, Meltem, Kuscu, Murat, Cetinkaya, Oktay, Ortlek, Beyza E., and Akan, Ozgur B.

Subjects

Computer Science - Emerging Technologies

Abstract

Internet of Bio-Nano Things (IoBNT) is a transformative communication framework, characterized by heterogeneous networks comprising both biological entities and artificial micro/nano-scale devices, so-called Bio-Nano Things (BNTs), interfaced with conventional communication networks for enabling innovative biomedical and environmental applications. Realizing the potential of IoBNT requires the development of new and unconventional communication technologies, such as molecular communications, as well as the corresponding transceivers, bio-cyber interfacing technologies connecting the biochemical domain of IoBNT to the electromagnetic domain of conventional networks, and miniaturized energy harvesting and storage components for the continuous power supply to BNTs. Graphene and related materials (GRMs) exhibit exceptional electrical, optical, biochemical, and mechanical properties, rendering them ideal candidates for addressing the challenges posed by IoBNT. This perspective article highlights recent advancements in GRM-based device technologies that are promising for implementing the core components of IoBNT. By identifying the unique opportunities afforded by GRMs and aligning them with the practical challenges associated with IoBNT, particularly in the materials domain, our aim is to accelerate the transition of envisaged IoBNT applications from theoretical concepts to practical implementations, while also uncovering new application areas for GRMs.

Published

2023

3. Frequency-Domain Detection for Molecular Communications

Author

Civas, Meltem, Abdali, Ali, Kuscu, Murat, and Akan, Ozgur B.

Subjects

Electrical Engineering and Systems Science - Signal Processing, Computer Science - Information Theory

Abstract

Molecular Communications (MC) is a bio-inspired communication paradigm which uses molecules as information carriers, thereby requiring unconventional transmitter/receiver architectures and modulation/detection techniques. Practical MC receivers (MC-Rxs) can be implemented based on field-effect transistor biosensor (bioFET) architectures, where surface receptors reversibly react with ligands, whose concentration encodes the information. The time-varying concentration of ligand-bound receptors is then translated into electrical signals via field-effect, which is used to decode the transmitted information. However, ligand-receptor interactions do not provide an ideal molecular selectivity, as similar types of ligands, i.e., interferers, co-existing in the MC channel can interact with the same type of receptors, resulting in cross-talk. Overcoming this molecular cross-talk with time-domain samples of the Rx's electrical output is not always attainable, especially when Rx has no knowledge of the interferer statistics or it operates near saturation. In this study, we propose a frequency-domain detection (FDD) technique for bioFET-based MC-Rxs, which exploits the difference in binding reaction rates of different types of ligands, reflected to the noise spectrum of the ligand-receptor binding fluctuations. We analytically derive the bit error probability (BEP) of the FDD technique, and demonstrate its effectiveness in decoding transmitted concentration signals under stochastic molecular interference, in comparison to a widely-used time-domain detection (TDD) technique. The proposed FDD method can be applied to any biosensor-based MC-Rxs, which employ receptor molecules as the channel-Rx interface.

Published

2023

4. Terahertz Wireless Communications in Space

Author

Civas, Meltem and Akan, Ozgur B.

Subjects

Computer Science - Emerging Technologies, Computer Science - Networking and Internet Architecture

Abstract

The New Space Era has increased communication traffic in space by new space missions led by public space agencies and private companies. Mars colonization is also targeted by crewed missions in the near future. Due to increasing space traffic near Earth and Mars, the bandwidth is getting congested. Moreover, the downlink performance of the current missions is not satisfactory in terms of delay and data rate. Therefore, to meet the increasing demand in space links, Terahertz band (0.1-10 THz) wireless communications are proposed in this study. In line with this, we discuss the major challenges that the realization of THz band space links pose and possible solutions. Moreover, we simulate Mars-space THz links for the case of a clear Mars atmosphere, and a heavy dust storm to show that even in the worst conditions, a large bandwidth is available for Mars communication traffic.

Published

2021

5. Universal Transceivers: Opportunities and Future Directions for the Internet of Everything (IoE)

Author

Civas, Meltem, Cetinkaya, Oktay, Kuscu, Murat, and Akan, Ozgur B.

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Emerging Technologies

Abstract

The Internet of Everything (IoE) is a recently introduced information and communication technology (ICT) framework promising for extending the human connectivity to the entire universe, which itself can be regarded as a natural IoE, an interconnected network of everything we perceive. The countless number of opportunities that can be enabled by IoE through a blend of heterogeneous ICT technologies across different scales and environments and a seamless interface with the natural IoE impose several fundamental challenges, such as interoperability, ubiquitous connectivity, energy efficiency, and miniaturization. The key to address these challenges is to advance our communication technology to match the multi-scale, multi-modal, and dynamic features of the natural IoE. To this end, we introduce a new communication device concept, namely the universal IoE transceiver, that encompasses transceiver architectures that are characterized by multi-modality in communication (with modalities such as molecular, RF/THz, optical and acoustic) and in energy harvesting (with modalities such as mechanical, solar, biochemical), modularity, tunability, and scalability. Focusing on these fundamental traits, we provide an overview of the opportunities that can be opened up by micro/nanoscale universal transceiver architectures towards realizing the IoE applications. We also discuss the most pressing challenges in implementing such transceivers and briefly review the open research directions. Our discussion is particularly focused on the opportunities and challenges pertaining to the IoE physical layer, which can enable the efficient and effective design of higher-level techniques. We believe that such universal transceivers can pave the way for seamless connection and communication with the universe at a deeper level and pioneer the construction of the forthcoming IoE landscape.

Published

2021

6. Molecular Communication Theoretical Modeling and Analysis of SARS-CoV2 Transmission in Human Respiratory System

Author

Koca, Caglar, Civas, Meltem, Sahin, Selin M., Ergonul, Onder, and Akan, Ozgur B.

Subjects

Physics - Biological Physics, Quantitative Biology - Tissues and Organs

Abstract

Severe Acute Respiratory Syndrome-CoronaVirus 2 (SARS-CoV2) caused the ongoing pandemic. This pandemic devastated the world by killing more than a million people, as of October 2020. It is imperative to understand the transmission dynamics of SARS-CoV2 so that novel and interdisciplinary prevention, diagnostic, and therapeutic techniques could be developed. In this work, we model and analyze the transmission of SARS-CoV2 through the human respiratory tract from a molecular communication perspective. We consider that virus diffusion occurs in the mucus layer so that the shape of the tract does not have a significant effect on the transmission. Hence, this model reduces the inherent complexity of the human respiratory system. We further provide the impulse response of SARS-CoV2-ACE2 receptor binding event to determine the proportion of the virus population reaching different regions of the respiratory tract. Our findings confirm the results in the experimental literature on higher mucus flow rate causing virus migration to the lower respiratory tract. These results are especially important to understand the effect of SARS-CoV2 on the different human populations at different ages who have different mucus flow rates and ACE2 receptor concentrations in the different regions of the respiratory tract., Comment: IEEE Transactions on Molecular, Biological, and Multi-Scale Communications

Published

2020

7. Information and Communication Theoretical Understanding and Treatment of Spinal Cord Injuries: State-of-the-art and Research Challenges

Author

Akan, Ozgur B., Ramezani, Hamideh, Civas, Meltem, Cetinkaya, Oktay, Bilgin, Bilgesu A., and Abbasi, Naveed A.

Subjects

Quantitative Biology - Neurons and Cognition, Computer Science - Emerging Technologies

Abstract

Among the various key networks in the human body, the nervous system occupies central importance. The debilitating effects of spinal cord injuries (SCI) impact a significant number of people throughout the world, and to date, there is no satisfactory method to treat them. In this paper, we review the major treatment techniques for SCI that include promising solutions based on information and communication technology (ICT) and identify the key characteristics of such systems. We then introduce two novel ICT-based treatment approaches for SCI. The first proposal is based on neural interface systems (NIS) with enhanced feedback, where the external machines are interfaced with the brain and the spinal cord such that the brain signals are directly routed to the limbs for movement. The second proposal relates to the design of self-organizing artificial neurons (ANs) that can be used to replace the injured or dead biological neurons. Apart from SCI treatment, the proposed methods may also be utilized as enabling technologies for neural interface applications by acting as bio-cyber interfaces between the nervous system and machines. Furthermore, under the framework of Internet of Bio- Nano Things (IoBNT), experience gained from SCI treatment techniques can be transferred to nano communication research., Comment: IEEE Reviews in Biomedical Engineering

Published

2020

8. Molecular communication theoretical modeling and analysis of SARS-CoV2 transmission in human respiratory system

Author

Civaş, Meltem; Şahin, Selin Merve; Ergönül, Mehmet Önder (ORCID 0000-0003-1935-9235 & YÖK ID 110398); Akan, Özgür Barış, Koca, Çağlar, Graduate School of Sciences and Engineering; School of Medicine; College of Engineering, Department of Electrical and Electronics Engineering, Civaş, Meltem; Şahin, Selin Merve; Ergönül, Mehmet Önder (ORCID 0000-0003-1935-9235 & YÖK ID 110398); Akan, Özgür Barış, Koca, Çağlar, Graduate School of Sciences and Engineering; School of Medicine; College of Engineering, and Department of Electrical and Electronics Engineering

Abstract

Severe Acute Respiratory Syndrome-CoronaVirus 2 (SARS-CoV2) caused the ongoing pandemic. This pandemic devastated the world by killing more than a million people, as of October 2020. It is imperative to understand the transmission dynamics of SARS-CoV2 so that novel and interdisciplinary prevention, diagnostic, and therapeutic techniques could be developed. In this work, we model and analyze the transmission of SARS-CoV2 through the human respiratory tract from a molecular communication perspective. We consider that virus diffusion occurs in the mucus layer so that the shape of the tract does not have a significant effect on the transmission. Hence, this model reduces the inherent complexity of the human respiratory system. We further provide the impulse response of SARS-CoV2-ACE2 receptor binding event to determine the proportion of the virus population reaching different regions of the respiratory tract. Our findings confirm the results in the experimental literature on higher mucus flow rate causing virus migration to the lower respiratory tract. These results are especially important to understand the effect of SARS-CoV2 on the different human populations at different ages who have different mucus flow rates and ACE2 receptor concentrations in the different regions of the respiratory tract., AXA Research Fund; Huawei Graduate Research Scholarship; Koç University İş Bank Research Center for Infectious Diseases (KUISCID)

Published

2021

9. Information and communication theoretical understanding and treatment of spinal cord injuries: state-of-the-art and research challenges

Author

Akan, Özgür Barış; Civaş, Meltem; Çetinkaya, Oktay; Ramezani, Hamideh; Abbasi, Naveed Ahmed, Bilgin, Bilgesu Arif, Graduate School of Sciences and Engineering; College of Engineering, Department of Electrical and Electronics Engineering, Akan, Özgür Barış; Civaş, Meltem; Çetinkaya, Oktay; Ramezani, Hamideh; Abbasi, Naveed Ahmed, Bilgin, Bilgesu Arif, Graduate School of Sciences and Engineering; College of Engineering, and Department of Electrical and Electronics Engineering

Abstract

Among the various key networks in the human body, the nervous system occupies central importance. The debilitating effects of spinal cord injuries (SCI) impact a significant number of people throughout the world, and to date, there is no satisfactory method to treat them. In this paper, we review the major treatment techniques for SCI that include promising solutions based on information and communication technology (ICT) and identify the key characteristics of such systems. We then introduce two novel ICT-based treatment approaches for SCI. The first proposal is based on neural interface systems (NIS) with enhanced feedback, where the external machines are interfaced with the brain and the spinal cord such that the brain signals are directly routed to the limbs for movement. The second proposal relates to the design of self-organizing artificial neurons (ANs) that can be used to replace the injured or dead biological neurons. Apart from SCI treatment, the proposed methods may also be utilized as enabling technologies for neural interface applications by acting as bio-cyber interfaces between the nervous system and machines. Furthermore, under the framework of Internet of BioNano Things (IoBNT), experience gained from SCI treatment techniques can be transferred to nano communication research., NA

Published

2021

10. Chapter 23 - Nanosensor networks for smart health care

Author

Khan, Tooba, Civas, Meltem, Cetinkaya, Oktay, Abbasi, Naveed A., and Akan, Ozgur B.

Published

2020

11. ICT-based understanding of spinal cord networks with applications to spinal cord injuries

Author

Civaş, Meltem, Akan, Özgür Barış, and Elektrik-Elektronik Mühendisliği Anabilim Dalı

Subjects

Communication networks, Elektrik ve Elektronik Mühendisliği, Synaptic transmission, Information and communications technology, Electrical and Electronics Engineering

Abstract

Nano teknoloji alanındaki çalışmalar, nano makinelerden oluşan nano ağların vücut içinde kullanılmalarının yolunu açmıştır. Nano ağların kullanımı ve Biyo-Nano nesnelerin interneti çatısı altında internete bağlanması, sinir sistemi hastalıkları tedavileri dahil sayısız biyomedikal uygulamalarla sonuçlanabilir. Moleküler haberleşme (MH), nano makineler arasında kullanım için önerilmiş bir haberleşme teknolojisidir. Biyolojik sistemlerin MH'nin en gelişmiş yöntemlerini kullanması, bilgi ve iletişim teknolojileri (BT) topluluğunu omurilik yaralanmaları (OY) gibi tedavisi olmayan sinir sistemi hastalıklarını nano düzeyde ve biyolojiden ilham alan tedavi yöntemleri geliştirmeye yöneltmektedir. Bu konuda, sinir sistemi hastalıklarını BT temelli tedavi ve teşhis yöntemleri geliştirmek için bir çatı önerilmiştir. Bu çatıya göre, sinir ağlarının anlayışı ve analizlerinden BT metriklerinin elde edilmesi bu tekniklerin geliştirilmesinde önemli faktörlerdir. Bu nedenle, bu tez omurilik ağlarının gerçekçi modellenmesi ve bilgi kuramı analizine eğilmektedir. Bu amaçla, haberleşme hızını analiz etmek için mevcut nöro atım haberleşme kanal modellerini omurilik ağına uygulamaktayız. Analizimi dayanarak, çeşitli omurilik yaralanmaları ve bilgi kuramı metrikleri arasında korelasyonlar elde etmekteyiz. Ayrıca, OY'den sonra bozulan sinir sistemi ağındaki haberleşmeyi yeniden sağlamak için mevcut ve biyo-ilhamlı ağ oluşturma/haberleşme tekniklerinin avantajlarını kullanabilen özgün BT temelli tedavi yöntemleri önermekteyiz. Research efforts in nanotechnology have opened the way for deployment of nanonetworks comprising nanomachines with bio-inspired capabilities inside the body. Deploying nanonetworks and connecting them to the Internet based on Internet of Bio-Nano Things (IoBNT) framework can result in wide range of possible biomedical applications including treatments techniques of nervous diseases. Molecular communication (MC) has been proposed as a communication technology solution to be employed among nanomachines. Since biological systems use most advanced forms of MC, this motivates information and communication technology (ICT) community to develop bio-inspired communication systems at the nanoscale for nervous system diseases such as spinal cord injuries (SCI), which cannot be recovered to the date by any treatment method. In this respect, a framework was proposed for developing ICT-based treatment and diagnosis tools for nervous diseases. According to this framework, understanding of nervous nanonetworks and extracting ICT metrics based on their analysis are the key steps for the development of these techniques. Hence, this thesis focuses on the realistic modeling and information theoretical analysis of spinal cord networks. To this end, we apply existing neuro-spike communication channel models to the particular spinal cord networks to analyze the rate of information flow across them. Based on our analysis, we obtain correlations between several types of spinal injuries and information theoretical metrics. Moreover, we further propose novel ICT-based treatment techniques which can use the advantages aspects of existing and bio-inspired communication/networking methods to recover disrupted communications in the nervous nanonetwork after SCI. 92

Published

2018

12. An information theoretical analysis of multi-terminal neuro-spike communication network in spinal cord

Author

Akan, Özgür Barış (ORCID & YÖK ID 6647); Civaş, Meltem, College of Engineering; Graduate School of Sciences and Engineering, Department of Electrical and Electronics Engineering, Akan, Özgür Barış (ORCID & YÖK ID 6647); Civaş, Meltem, College of Engineering; Graduate School of Sciences and Engineering, and Department of Electrical and Electronics Engineering

Abstract

Communication theoretical understanding of healthy and diseased connections in the spinal cord motor system is crucial for realizing future information and communication technology (ICT) based diagnosis and treatment techniques for spinal cord injuries (SCI). A spinal cord motor nucleus associated with a particular muscle constitutes an ideal candidate for studying to have an understanding of SCI. Typical spinal cord motor nucleus system contains pool of lower motor neurons (MNs) controlling a muscle by integrating synaptic inputs from spinal interneurons (INs), upper motor neurons (DNs) and sensory neurons (SNs). In this study, we consider this system from ICT perspective. Our aim is to quantify the rate of information flow across a spinal cord motor nucleus. To this end, we model an equivalent single-hop multiterminal network, where multiple transmitting nodes representing heterogeneous population of DNs, INs and SNs sen information to multiple receiving nodes corresponding to MNs. To identify the outputs at receiving nodes, we define corresponding neurospike communication channel and then find the bound on total rates across this network. Based on the network model, we analyze achievable rates for a particular motor nucleus system called Tibialis Anterior (TA) motor nucleus in the spinal cord numerically and simulate several spinal cord dysfunction scenarios. The numerical results reveal that decrease in the maximum total rates with the lower motor neuron injury causes weakness in the affected muscle., European Union (European Union); European Research Council (ERC) Projects MINERVA; European Research Council (ERC) Proof of Concept Project MINERGRACE

Published

2018

13. List of contributors

Author

Abbasi, Naveed A., Abnous, Khalil, Akan, Ozgur B., Akhtar, Javeed, Alencar, Marcelo S., Alibolandi, Mona, Alvarado, Mainor Cruz, Amorin, Luís Henrique, Awan, Fazli Rabbi, Bajwa, Sadia Z., Bakirhan, Nurgul K., Bazán, Patricia, Benavente-Peces, Cesar, Bhatt, Purvi, Bhatti, Haq Nawaz, Biasotto, Glenda, Bouvry, Pascal, Camargo, Emerson Rodrigues, Capponi, Andrea, Carey, Patrick, IV, Cetinkaya, Oktay, Chaudhary, Vandna, Cincotto, Fernando Henrique, Civas, Meltem, Daghooghi, Tina, Denizli, Adil, El Barachi, May, Esmaelpourfarkhani, Masoomeh, Farkas, Károly, Farmani, Ali, Felix, Anderson A., Fiandrino, Claudio, Flores-Fuentes, Wendy, Fonseca, Iguatemi E., Garcia, Cristobal, Gebhard, Michael, Ghodrati, Maryam, Ghosh, Rinky, Gomes, Ruan D., Gonzalez-Navarro, Félix F., Gorup, Luiz Fernando, Guo, Longhua, Habib-ur-Rehman, Hannachi, Essia, Hayat, Hunza, Hernández-Balbuena, Daniel, Imanzadeh, Hamideh, Joshi, Nirav, Kannan, Palanisamy, Karadurmus, Leyla, Kaya, Sariye Irem, Khalid, Waqas, Khan, Tooba, Khan, Waheed S., Kliazovich, Dzmitry, Kornyushchenko, Anna, La Porta, Felipe de Almeida, Leon, Marino E., Li, Yongxin, Lin, Jenshan, Lin, Liwei, Lindner, Lars, Lobo, Brian C., Malik, Ritu, Mir, Ali, Miranda-Vega, Jesús E., Mohammad, Shoaib, Motaung, David E., Mourad, Azzam, Mozaffari, Mohammad Hazhir, Nazari, Atefeh, Oosthuizen, Dina N., Orabi, Wael Al, Orlandi, Marcelo O., Oroojalian, Fatemeh, Ozcelikay, Goksu, Ozkan, Sibel A., Patel, Gautam, Pearton, S.J., Perekrestov, Vyacheslav, Pillai, Vineeta, Queiroz, Diego V., Rahman, Sawsan Abdul, Ramesar, Naomi, Ramezani, Mohammad, Rawat, Neha Kanwar, Ren, Fan, Rivas-López, Moisés, Rodríguez-Quiñonez, Julio C., Rydosz, Artur, Saylan, Yeşeren, Sequinel, Thiago, Sergiyenko, Oleg, Shaheen, Ayesha, Singh, Priyanka, Slimani, Yassine, Soroosh, Mohammad, Suman, Pedro H., Swart, Hendrik C., Sınag, Ali, Taghdisi, Seyed Mohammad, Taj, Ayesha, Tang, Haoran, Tomer, Vijay K., Trendafilova, Irina, Tshabalala, Zamaswazi P., Tyrsa, Vera, Wang, Hao, Wilde, Gerhard, Yadava, R.D.S., Yang, Jiancheng, Yazdian-Robati, Rezvan, Younis, Sumaira, and Zia, Rabisa

Published

2020

14. Molecular communication theoretical modeling and analysis of SARS-CoV2 transmission in human respiratory system

Author

Meltem Civas, Ozgur B. Akan, Caglar Koca, Selin Merve Sahin, Onder Ergonul, Civaş, Meltem, Şahin, Selin Merve, Ergönül, Mehmet Önder (ORCID 0000-0003-1935-9235 & YÖK ID 110398), Akan, Özgür Barış, Koca, Çağlar, Graduate School of Sciences and Engineering, School of Medicine, College of Engineering, and Department of Electrical and Electronics Engineering

Subjects

Computer Networks and Communications, Population, FOS: Physical sciences, Bioengineering, Biology, Virus, Pandemic, medicine, Physics - Biological Physics, Electrical and Electronic Engineering, Respiratory system, education, Tissues and Organs (q-bio.TO), education.field_of_study, Molecular communication, Transmission (medicine), SARS-CoV2, 2019-n-Cov, Quantitative Biology - Tissues and Organs, Mucus, medicine.anatomical_structure, Biological Physics (physics.bio-ph), Modeling and Simulation, FOS: Biological sciences, Immunology, Biotechnology, Respiratory tract

Abstract

Severe Acute Respiratory Syndrome-CoronaVirus 2 (SARS-CoV2) caused the ongoing pandemic. This pandemic devastated the world by killing more than a million people, as of October 2020. It is imperative to understand the transmission dynamics of SARS-CoV2 so that novel and interdisciplinary prevention, diagnostic, and therapeutic techniques could be developed. In this work, we model and analyze the transmission of SARS-CoV2 through the human respiratory tract from a molecular communication perspective. We consider that virus diffusion occurs in the mucus layer so that the shape of the tract does not have a significant effect on the transmission. Hence, this model reduces the inherent complexity of the human respiratory system. We further provide the impulse response of SARS-CoV2-ACE2 receptor binding event to determine the proportion of the virus population reaching different regions of the respiratory tract. Our findings confirm the results in the experimental literature on higher mucus flow rate causing virus migration to the lower respiratory tract. These results are especially important to understand the effect of SARS-CoV2 on the different human populations at different ages who have different mucus flow rates and ACE2 receptor concentrations in the different regions of the respiratory tract., Comment: IEEE Transactions on Molecular, Biological, and Multi-Scale Communications

Published

2021

15. Information and Communication Theoretical Understanding and Treatment of Spinal Cord Injuries: State-of-the-art and Research Challenges

Author

Meltem Civas, Oktay Cetinkaya, Bilgesu A. Bilgin, Hamideh Ramezani, Naveed A. Abbasi, Ozgur B. Akan, Akan, Özgür Barış, Civaş, Meltem, Çetinkaya, Oktay, Ramezani, Hamideh, Abbasi, Naveed Ahmed, Bilgin, Bilgesu Arif, Graduate School of Sciences and Engineering, College of Engineering, and Department of Electrical and Electronics Engineering

Subjects

Nervous system, FOS: Computer and information sciences, Nano communication, Computer science, Biomedical Engineering, Computer Science - Emerging Technologies, 02 engineering and technology, 03 medical and health sciences, 0302 clinical medicine, Brain computer interface, Motor cortex, Decoding, Human–computer interaction, medicine, Brain–computer interface, business.industry, 021001 nanoscience & nanotechnology, Spinal cord, 3. Good health, medicine.anatomical_structure, Emerging Technologies (cs.ET), Artificial neurons, Axons, Injuries, Muscles, Neural interface systems, Neurons, Spinal cord injuries, Spinal cord injury, Spinal treatments, Synapses, Information and Communications Technology, Quantitative Biology - Neurons and Cognition, FOS: Biological sciences, Key (cryptography), The Internet, Neurons and Cognition (q-bio.NC), State (computer science), 0210 nano-technology, business, 030217 neurology & neurosurgery

Abstract

Among the various key networks in the human body, the nervous system occupies central importance. The debilitating effects of spinal cord injuries (SCI) impact a significant number of people throughout the world, and to date, there is no satisfactory method to treat them. In this paper, we review the major treatment techniques for SCI that include promising solutions based on information and communication technology (ICT) and identify the key characteristics of such systems. We then introduce two novel ICT-based treatment approaches for SCI. The first proposal is based on neural interface systems (NIS) with enhanced feedback, where the external machines are interfaced with the brain and the spinal cord such that the brain signals are directly routed to the limbs for movement. The second proposal relates to the design of self-organizing artificial neurons (ANs) that can be used to replace the injured or dead biological neurons. Apart from SCI treatment, the proposed methods may also be utilized as enabling technologies for neural interface applications by acting as bio-cyber interfaces between the nervous system and machines. Furthermore, under the framework of Internet of Bio- Nano Things (IoBNT), experience gained from SCI treatment techniques can be transferred to nano communication research., Comment: IEEE Reviews in Biomedical Engineering

Published

2020

16. An information theoretical analysis of multi-terminal neuro-spike communication network in spinal cord

Author

Meltem Civas, Ozgur B. Akan, Akan, Özgür Barış (ORCID & YÖK ID 6647), Civaş, Meltem, College of Engineering, Graduate School of Sciences and Engineering, and Department of Electrical and Electronics Engineering

Subjects

Computer science, Multi-terminal networks, Neuro-spike communication, Sensory system, 02 engineering and technology, Hardware and architecture, Engineering, electrical and electronic, Telecommunications, Spinal cord injuries, ICT-based treatments, Nanonetworks, 021001 nanoscience & nanotechnology, Spinal cord, Telecommunications network, Lower motor neuron, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Terminal (electronics), Motor system, medicine, Nanoscience and nanotechnology, 0210 nano-technology, Neuroscience, Nucleus, Spinal Cord Injuries, 030217 neurology & neurosurgery, Network model

Abstract

Communication theoretical understanding of healthy and diseased connections in the spinal cord motor system is crucial for realizing future information and communication technology (ICT) based diagnosis and treatment techniques for spinal cord injuries (SCI). A spinal cord motor nucleus associated with a particular muscle constitutes an ideal candidate for studying to have an understanding of SCI. Typical spinal cord motor nucleus system contains pool of lower motor neurons (MNs) controlling a muscle by integrating synaptic inputs from spinal interneurons (INs), upper motor neurons (DNs) and sensory neurons (SNs). In this study, we consider this system from ICT perspective. Our aim is to quantify the rate of information flow across a spinal cord motor nucleus. To this end, we model an equivalent single-hop multiterminal network, where multiple transmitting nodes representing heterogeneous population of DNs, INs and SNs sen information to multiple receiving nodes corresponding to MNs. To identify the outputs at receiving nodes, we define corresponding neurospike communication channel and then find the bound on total rates across this network. Based on the network model, we analyze achievable rates for a particular motor nucleus system called Tibialis Anterior (TA) motor nucleus in the spinal cord numerically and simulate several spinal cord dysfunction scenarios. The numerical results reveal that decrease in the maximum total rates with the lower motor neuron injury causes weakness in the affected muscle., European Union (European Union); European Research Council (ERC) Projects MINERVA; European Research Council (ERC) Proof of Concept Project MINERGRACE

Published

2018