152 |                                                             Badr, Murdas & Aldhahab

[21] T. Khan, M. Civas, O. Cetinkaya, N. A. Abbasi, and           [31] H. Zerrouki and S. Azzaz-Rahmani, “Design of dual-
      O. B. Akan, “Nanosensor networks for smart health care,”          band (mics and ism) implantable antenna for wireless
      in Nanosensors for Smart Cities, Elsevier, p. 387–403,            medical telemetry applications,” Journal of Electrical
      2020.                                                             Systems, vol. 17, no. 3, 2021.

[22] Q. Rubani, G. R. Begh, and S. H. Gupta, “Design and          [32] K. Ramamoorthy, K. R. Kiran, E. Thangaselvi,
      investigation of a mimo nanoantenna operating at optical          S. Karthikeyan, and T. Chelladurai, “Design and analysis
      frequency,” Optik (Stuttg), vol. 223, p. 165481, 2020.            of square microstrip patch antenna at 2.4 ghz band used
                                                                        for iot based health care monitoring,” in AIP Conference
[23] S. Dash and A. Patnaik, “Impact of silicon-based sub-              Proceedings, AIP Publishing LLC, p. 030020, 2022.
      strates on graphene thz antenna,” Physica E Low Dimens
      Syst Nanostruct, vol. 126, p. 114479, 2021.                 [33] G. P. Ramesh, H. Abdullah, and B. D. Parameshachari,
                                                                        “Design and comparative analysis of microstrip patch an-
[24] D. Samanta, M. P. Karthikeyan, A. Banerjee, and                    tenna by using various materials in hfss,” in Distributed
      H. Inokawa, “Tunable graphene nanopatch antenna de-               Computing and Optimization Techniques: Select Pro-
      sign for on-chip integrated terahertz detector arrays with        ceedings of ICDCOT 2021, Springer, p. 303–312, 2022.
      potential application in cancer imaging,” Nanomedicine,
      vol. 16, no. 12, p. 1035–1047, 2021.                        [34] S. Suganthi and P. T. Selvan, “Trapezoidal microstrip
                                                                        patch antenna array for low frequency medical ap-
[25] S. S. Singhwal, L. Matekovits, I. Peter, and B. K.                 plications,” Wirel Pers Commun, vol. 126, no. 2,
      Kanaujia, “Application of dielectric resonator antenna            p. 1721–1732, 2022.
      in implantable medical devices,” in 2021 IEEE Inter-
      national Symposium on Antennas and Propagation and          [35] E. Thangaselvi, E. Kumaraswamy, K. Ramamoorthy,
      USNC-URSI Radio Science Meeting (APS/URSI), IEEE,                 S. Karthikeyan, and T. Chelladurai, “Design and fabrica-
      p. 80–81, 2021.                                                   tion of rectangular microstrip patch antenna at ism band
                                                                        for medical applications,” in AIP Conference Proceed-
[26] E. Thangaselvi and K. M. alias Jeyanthi, “Implementa-              ings, AIP Publishing LLC, p. 030015, 2022.
      tion of flexible denim nickel copper rip stop textile an-
      tenna for medical application,” Cluster Comput, vol. 22,    [36] S. S. V. et al., “Design of uwb wearable microstrip
      p. 635–645, 2019.                                                 patch antenna for wireless body worn applications,”
                                                                        in AIP Conference Proceedings, AIP Publishing LLC,
[27] A. Othman, N. I. S. Shaari, A. M. Zobilah, N. A. Shairi,           p. 020158, 2023.
      and Z. Zakaria, “Design of compact ultra-wideband an-
      tenna for microwave medical imaging application,” In-       [37] R. Prasanna, G. T. Selvi, K. Annaram, K. Venkatalak-
      donesian Journal of Electrical Engineering and Com-               shmi, M. Jenath, and B. P. Prathaban, “Multiband flexi-
      puter Science (IJEECS), vol. 15, no. 3, p. 1197–1202,             ble ultra-wideband antenna for wearable electronics and
      2019.                                                             biomedical applications,” Int J Multiscale Comput Eng,
                                                                        vol. 21, 2023.
[28] R. J. et al., “Analysis and design of dual-band folded-
      shorted patch antennas for robust wearable applications,”   [38] H. Kaur and P. Chawla, “Design and evaluation of a
      IEEE Open Journal of Antennas and Propagation, vol. 1,            fractal wearable textile antenna for medical applications,”
      p. 239–252, 2020.                                                 Wirel Pers Commun, vol. 128, no. 1, p. 683–699, 2023.

[29] N. A. Malik, T. Ajmal, P. Sant, and M. Ur-Rehman,            [39] P. K. S. Purnendu, A. B. Anwar, R. Islam, D. Mollik,
      “A compact size implantable antenna for bio-medical               M. A. Hossain, and M. Ahmad, “Design of 8× 8 mi-
      applications,” in 2020 International Conference on UK-            crostrip array antenna for ism and k-band applications,”
      China Emerging Technologies (UCET), IEEE, pp. 1–4,                in Proceedings of International Conference on Informa-
      2020.                                                             tion and Communication Technology for Development:
                                                                        ICICTD 2022, Springer, p. 153–162, 2023.

[30] C. Gayathri and S. Venkatanarayanan, “A miniaturized         [40] M. S. Rana, O. Islam, S. A. Shikha, and M. Faisal, “Iot
      circular maze shaped antenna for implantable health care          application using a rectangular 2.4 ghz microstrip patch
      applications,” J Ambient Intell Humaniz Comput, vol. 12,          antenna,” in 2023 International Conference for Advance-
      p. 4757–4763, 2021.                                               ment in Technology (ICONAT), IEEE, p. 1–4, 2023.