Your search keyword '"Kuscu, Murat"' showing total 9 results

1. Maximum Likelihood Detection With Ligand Receptors for Diffusion-Based Molecular Communications in Internet of Bio-Nano Things.

Author

Kuscu M and Akan OB

Subjects

Diffusion, Ligands, Models, Biological, Biotechnology methods, Computers, Molecular, Internet, Nanotechnology methods

Abstract

Molecular Communication (MC) is a bio-inspired communication technique that uses molecules as a method of information transfer among nanoscale devices. MC receiver is an essential component having profound impact on the communication system performance. However, the interaction of the receiver with information bearing molecules has been usually oversimplified in modeling the reception process and developing signal detection techniques. In this paper, we focus on the signal detection problem of MC receivers employing receptor molecules to infer the transmitted messages encoded into the concentration of molecules, i.e., ligands. Exploiting the observable characteristics of ligand-receptor binding reaction, we first introduce a Maximum Likelihood (ML) detection method based on instantaneous receptor occupation ratio, as aligned with the current MC literature. Then, we propose a novel ML detection technique, which exploits the amount of time the receptors stay unbound in an observation time window. A comprehensive analysis is carried out to compare the performance of the detectors in terms of bit error probability. In evaluating the detection performance, emphasis is given to the receptor saturation problem resulting from the accumulation of messenger molecules at the receiver as a consequence of intersymbol interference. The results reveal that detection based on receptor unbound time is quite reliable even in saturation, whereas the reliability of detection based on receptor occupation ratio substantially decreases as the receiver gets saturated. Finally, we also discuss the potential methods of implementing the detectors.

Published

2018

2. Modeling convection-diffusion-reaction systems for microfluidic molecular communications with surface-based receivers in Internet of Bio-Nano Things.

Author

Kuscu M and Akan OB

Subjects

Finite Element Analysis, Surface Properties, Internet, Microfluidics, Models, Theoretical, Nanotechnology

Abstract

We consider a microfluidic molecular communication (MC) system, where the concentration-encoded molecular messages are transported via fluid flow-induced convection and diffusion, and detected by a surface-based MC receiver with ligand receptors placed at the bottom of the microfluidic channel. The overall system is a convection-diffusion-reaction system that can only be solved by numerical methods, e.g., finite element analysis (FEA). However, analytical models are key for the information and communication technology (ICT), as they enable an optimisation framework to develop advanced communication techniques, such as optimum detection methods and reliable transmission schemes. In this direction, we develop an analytical model to approximate the expected time course of bound receptor concentration, i.e., the received signal used to decode the transmitted messages. The model obviates the need for computationally expensive numerical methods by capturing the nonlinearities caused by laminar flow resulting in parabolic velocity profile, and finite number of ligand receptors leading to receiver saturation. The model also captures the effects of reactive surface depletion layer resulting from the mass transport limitations and moving reaction boundary originated from the passage of finite-duration molecular concentration pulse over the receiver surface. Based on the proposed model, we derive closed form analytical expressions that approximate the received pulse width, pulse delay and pulse amplitude, which can be used to optimize the system from an ICT perspective. We evaluate the accuracy of the proposed model by comparing model-based analytical results to the numerical results obtained by solving the exact system model with COMSOL Multiphysics.

Published

2018

3. FRET-based nanoscale point-to-point and broadcast communications with multi-exciton transmission and channel routing.

Author

Kuscu M and Akan OB

Subjects

Algorithms, Fluorescent Dyes, Monte Carlo Method, Communication, Computers, Molecular, Fluorescence Resonance Energy Transfer methods, Nanotechnology methods

Abstract

Nanoscale communication based on Förster Resonance Energy Transfer (FRET) enables nanoscale single molecular devices to communicate with each other utilizing excitons generated on fluorescent molecules as information carriers. Based on the point-to-point single-exciton FRET-based nanocommunication model, we investigate the multiple-exciton case for point-to-point and broadcast communications following an information theoretical approach and conducting simulations through Monte Carlo approach. We demonstrate that the multi-exciton transmission significantly improves the channel reliability and the range of the communication up to tens of nanometers for immobile nanonodes providing high data transmission rates. Furthermore, our analyses indicate that multi-exciton transmission enables broadcasting of information from a transmitter nanonode to many receiver nanonodes pointing out the potential of FRET-based communication to extend over nanonetworks. In this study, we also propose electrically and chemically controllable routing mechanisms exploiting the strong dependence of FRET rate on spectral and spatial characteristics of fluorescent molecules. We show that the proposed routing mechanisms enable the remote control of information flow in FRET-based nanonetworks. The high transmission rates obtained by multi-exciton scheme for point-to-point and broadcast communications, as well as the routing opportunities make FRET-based communication promising for future molecular computers.

Published

2014

4. A communication theoretical analysis of FRET-based mobile ad hoc molecular nanonetworks.

Author

Kuscu M and Akan OB

Subjects

Communication, Fluorescent Dyes chemistry, Markov Chains, Computers, Molecular, Fluorescence Resonance Energy Transfer methods, Nanotechnology methods

Abstract

Nanonetworks refer to a group of nanosized machines with very basic operational capabilities communicating to each other in order to accomplish more complex tasks such as in-body drug delivery, or chemical defense. Realizing reliable and high-rate communication between these nanomachines is a fundamental problem for the practicality of these nanonetworks. Recently, we have proposed a molecular communication method based on Förster Resonance Energy Transfer (FRET) which is a nonradiative excited state energy transfer phenomenon observed among fluorescent molecules, i.e., fluorophores. We have modeled the FRET-based communication channel considering the fluorophores as single-molecular immobile nanomachines, and shown its reliability at high rates, and practicality at the current stage of nanotechnology. In this study, for the first time in the literature, we investigate the network of mobile nanomachines communicating through FRET. We introduce two novel mobile molecular nanonetworks: FRET-based mobile molecular sensor/actor nanonetwork (FRET-MSAN) which is a distributed system of mobile fluorophores acting as sensor or actor node; and FRET-based mobile ad hoc molecular nanonetwork (FRET-MAMNET) which consists of fluorophore-based nanotransmitter, nanoreceivers and nanorelays. We model the single message propagation based on birth-death processes with continuous time Markov chains. We evaluate the performance of FRET-MSAN and FRET-MAMNET in terms of successful transmission probability and mean extinction time of the messages, system throughput, channel capacity and achievable communication rates.

Published

2014

5. Toward Interdisciplinary Synergies in Molecular Communications: Perspectives from Synthetic Biology, Nanotechnology, Communications Engineering and Philosophy of Science.

Author

Egan, Malcolm, Kuscu, Murat, Barros, Michael Taynnan, Booth, Michael, Llopis-Lorente, Antoni, Magarini, Maurizio, Martins, Daniel P., Schäfer, Maximilian, and Stano, Pasquale

Subjects

*PHILOSOPHY of science, *SYNTHETIC biology, *NANOTECHNOLOGY, *CHEMICAL systems, *BIOLOGICAL systems

Abstract

Within many chemical and biological systems, both synthetic and natural, communication via chemical messengers is widely viewed as a key feature. Often known as molecular communication, such communication has been a concern in the fields of synthetic biologists, nanotechnologists, communications engineers, and philosophers of science. However, interactions between these fields are currently limited. Nevertheless, the fact that the same basic phenomenon is studied by all of these fields raises the question of whether there are unexploited interdisciplinary synergies. In this paper, we summarize the perspectives of each field on molecular communications, highlight potential synergies, discuss ongoing challenges to exploit these synergies, and present future perspectives for interdisciplinary efforts in this area. [ABSTRACT FROM AUTHOR]

Published

2023

6. Multi-Step FRET-Based Long-Range Nanoscale Communication Channel.

Author

Kuscu, Murat and Akan, Ozgur B.

Subjects

FLUORESCENCE resonance energy transfer, NANOELECTROMECHANICAL systems, COMMUNICATION, FLUOROPHORES, NANOTECHNOLOGY, NANOSENSORS

Abstract

Nanoscale communication based on Forster Resonance Energy Transfer (FRET) is a promising paradigm that allows future molecular-size machines to communicate with each other over distances up to 10 nm using the excited state energies of fluorescent molecules. In this study, we propose a novel nanoscale communication method based on multi-step FRET using identical fluorophores as relay nodes between communicating nanomachines, and utilizing multi-exciton transmission scheme in order to improve the limited range of the communication and achievable transmission rate over the nanoscale channel. We investigate two communication scenarios: immobile nanomachines communicating through a channel in a host material with linearly located relay nodes, and mobile nanomachines communicating through a channel in a 3-dimensional aqueous environment with randomly deployed relay nodes. We simulate the communication over these channels with realistic algorithms considering the high degree of randomness intrinsic to FRET phenomenon. Using the simulation results and following a Monte Carlo approach, we evaluate the performance of the channels by means of information theoretical capacity and interference probability. We show that multi-step FRET-based communication significantly outperforms the other biologically inspired nanocommunication techniques proposed so far in terms of maximum achievable data transmission rates. The results underline the compatibility and practicality of the FRET-based communication for several applications ranging from molecular computers to nanosensor networks. [ABSTRACT FROM PUBLISHER]

Published

2013

7. Fluorescent Molecules as Transceiver Nanoantennas: The First Practical and High-Rate Information Transfer over a Nanoscale Communication Channel based on FRET.

Author

Akan, Ozgur B., Kuscu, Murat, and Kiraz, Alper

Subjects

*FLUORESCENCE resonance energy transfer, *OPTICAL antennas, *FLUOROPHORES, *NANONETWORKS, *COMMUNICATION & technology, *NANOTECHNOLOGY

Abstract

Nanocommunications via Förster Resonance Energy Transfer (FRET) is a promising means of realising collaboration between photoactive nanomachines to implement advanced nanotechnology applications. The method is based on exchange of energy levels between fluorescent molecules by the FRET phenomenon which intrinsically provides a virtual nanocommunication link. In this work, further to the extensive theoretical studies, we demonstrate the first information transfer through a FRET-based nanocommunication channel. We implement a digital communication system combining macroscale transceiver instruments and a bulk solution of fluorophore nanoantennas. The performance of the FRET-based Multiple-Input and Multiple-Output (MIMO) nanocommunication channel between closely located mobile nanoantennas in the sample solution is evaluated in terms of Signal-to-Noise Ratio (SNR) and Bit Error Rate (BER) obtained for the transmission rates of 50 kbps, 150 kbps and 250 kbps. The results of the performance evaluation are very promising for the development of high-rate and reliable molecular communication networks at nanoscale. [ABSTRACT FROM AUTHOR]

Published

2015

8. Modeling convection-diffusion-reaction systems for microfluidic molecular communications with surface-based receivers in Internet of Bio-Nano Things

Author

Ozgur B. Akan, Murat Kuscu, Kuscu, Murat [0000-0002-8463-6027], Apollo - University of Cambridge Repository, Kuşçu, Murat, Akan, Özgür Barış, College of Engineering, Graduate School of Sciences and Engineering, and Department of Electrical and Electronics Engineering

Subjects

Computer science, Microfluidics, lcsh:Medicine, 02 engineering and technology, Pharmacokinetic Analysis, Signal, Compartment Models, Laminar Flow, 0202 electrical engineering, electronic engineering, information engineering, Medicine and Health Sciences, Nanotechnology, lcsh:Science, Multidisciplinary, Molecular communication, Physics, Applied Mathematics, Classical Mechanics, 021001 nanoscience & nanotechnology, Finite element method, On-a-chip, Mass-transport, Rate constants, Biosensors, Channels, Information, Technology, Biacore, Binding, Design, Physical Sciences, Telecommunications, Engineering and Technology, Fluidics, 0210 nano-technology, Research Article, Biotechnology, Convection, Two-Compartment Models, Mass transport, Surface Properties, Multiphysics, Finite Element Analysis, Fluid Mechanics, Topology, Continuum Mechanics, Multidisciplinary sciences, System model, Microfluidic channel, Fluid Flow, Pharmacology, FOS: Nanotechnology, Internet, Numerical analysis, lcsh:R, Biology and Life Sciences, 020206 networking & telecommunications, Laminar flow, Fluid Dynamics, Models, Theoretical, Pharmacologic Analysis, Bionanotechnology, lcsh:Q, Convection–diffusion equation, Mathematics

Abstract

We consider a microfluidic molecular communication (MC) system, where the concentration-encoded molecular messages are transported via fluid flow-induced convection and diffusion, and detected by a surface-based MC receiver with ligand receptors placed at the bottom of the microfluidic channel. The overall system is a convection-diffusion-reaction system that can only be solved by numerical methods, e.g., finite element analysis (FEA). However, analytical models are key for the information and communication technology (ICT), as they enable an optimisation framework to develop advanced communication techniques, such as optimum detection methods and reliable transmission schemes. In this direction, we develop an analytical model to approximate the expected time course of bound receptor concentration, i.e., the received signal used to decode the transmitted messages. The model obviates the need for computationally expensive numerical methods by capturing the nonlinearities caused by laminar flow resulting in parabolic velocity profile, and finite number of ligand receptors leading to receiver saturation. The model also captures the effects of reactive surface depletion layer resulting from the mass transport limitations and moving reaction boundary originated from the passage of finite-duration molecular concentration pulse over the receiver surface. Based on the proposed model, we derive closed form analytical expressions that approximate the received pulse width, pulse delay and pulse amplitude, which can be used to optimize the system from an ICT perspective. We evaluate the accuracy of the proposed model by comparing model-based analytical results to the numerical results obtained by solving the exact system model with COMSOL Multiphysics., European Union (EU); H2020; ERC project MINERVA; EU project CIRCLE

Published

2018

9. Maximum likelihood detection with Ligand receptors for diffusion-based molecular communications in internet of bio-nano things

Author

Ozgur B. Akan, Murat Kuscu, Akan, Özgür Barış, Kuşçu, Murat, Graduate School of Sciences and Engineering, Department of Electrical and Electronics Engineering, Kuscu, Murat [0000-0002-8463-6027], Akan, Ozgur [0000-0003-2523-3858], and Apollo - University of Cambridge Repository

Subjects

Information transfer, Computer science, Reliability (computer networking), Biomedical Engineering, Pharmaceutical Science, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, Communications system, Ligands, Models, Biological, Diffusion, Computers, Molecular, 0202 electrical engineering, electronic engineering, information engineering, Nanotechnology, Detection theory, Electrical and Electronic Engineering, Internet, FOS: Nanotechnology, Molecular communication, Detector, Emphasis (telecommunications), 020206 networking & telecommunications, 021001 nanoscience & nanotechnology, Computer Science Applications, Intersymbol interference, Receiver, Ligand receptors, Maximum-likelihood estimation, Signal detection, 0210 nano-technology, Biochemistry and molecular biology, Science and technology, Algorithm, Biotechnology

Abstract

Molecular Communication (MC) is a bioinspired communication technique that uses molecules as a method of information transfer among nanoscale devices. MC receiver is an essential component having profound impact on the communication system performance. However, the interaction of the receiver with information bearing molecules has been usually oversimplified in modeling the reception process and developing signal detection techniques. In this paper, we focus on the signal detection problem of MC receivers employing receptor molecules to infer the transmitted messages encoded into the concentration of molecules, i.e., ligands. Exploiting the observable characteristics of ligand-receptor binding reaction, we first introduce a Maximum Likelihood (ML) detection method based on instantaneous receptor occupation ratio, as aligned with the current MC literature. Then, we propose a novel ML detection technique, which exploits the amount of time the receptors stay unbound in an observation time window. A comprehensive analysis is carried out to compare the performance of the detectors in terms of bit error probability. In evaluating the detection performance, emphasis is given to the receptor saturation problem resulting from the accumulation of messenger molecules at the receiver as a consequence of intersymbol interference. The results reveal that detection based on receptor unbound time is quite reliable even in saturation, whereas the reliability of detection based on receptor occupation ratio substantially decreases as the receiver gets saturated. Finally, we also discuss the potential methods of implementing the detectors., European Research Council (ERC); European Union (European Union); H2020; MINERVA; CIRCLE

Published

2018