Abstract

This paper presents a sustainable biocyber interface approach for an intelligent targeted drug delivery system (TDDS). The proposed approach employs a bioinspired molecular communications (MC) system in which molecules are used as information carriers and a multi-input multi-output (MIMO) Forster resonance energy transfer (FRET) nanorelay to efficiently transfer therapeutic drugs from extravascular (outside blood vessels) to intravascular (within blood vessels) sites that are targeting diseased tissue. The proposed approach consists of a number of bio-nano things (BNTs) implanted inside the human intra-body nanonetwork near the diseased site. The communication among BNTs is accomplished by a sequential multistep FRET, and the nanonetwork is controlled by the Internet of Bio-Nano Thing (IoBNT) paradigm sustained by an uplink/downlink biocyber interface. The bit error rate (BER) and molecular channel capacity are utilized to evaluate the performance of the proposed approach. In addition, a Markov model decision in terms of the number of nanomachines is presented to calculate the successful probability of drug delivery and the average delay time. The numerical results show how effective the suggested method is at transmitting therapeutic medication information with an attainable bit-rate error.

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