[go: up one dir, main page]
More Web Proxy on the site http://driver.im/ skip to main content
research-article

Networking Architecture and Key Supporting Technologies for Human Digital Twin in Personalized Healthcare: A Comprehensive Survey

Published: 04 September 2023 Publication History

Abstract

Digital twin (DT), referring to a promising technique to digitally and accurately represent actual physical entities, has attracted explosive interests from both academia and industry. One typical advantage of DT is that it can be used to not only virtually replicate a system’s detailed operations but also analyze the current condition, predict the future behavior, and refine the control optimization. Although DT has been widely implemented in various fields, such as smart manufacturing and transportation, its conventional paradigm is limited to embody non-living entities, e.g., robots and vehicles. When adopted in human-centric systems, a novel concept, called human digital twin (HDT) has thus been proposed. Particularly, HDT allows in silico representation of individual human body with the ability to dynamically reflect molecular status, physiological status, emotional and psychological status, as well as lifestyle evolutions. These prompt the expected application of HDT in personalized healthcare (PH), which can facilitate the remote monitoring, diagnosis, prescription, surgery and rehabilitation, and hence significantly alleviate the heavy burden on the traditional healthcare system. However, despite the large potential, HDT faces substantial research challenges in different aspects, and becomes an increasingly popular topic recently. In this survey, with a specific focus on the networking architecture and key technologies for HDT in PH applications, we first discuss the differences between HDT and the conventional DTs, followed by the universal framework and essential functions of HDT. We then analyze its design requirements and challenges in PH applications. After that, we provide an overview of the networking architecture of HDT, including data acquisition layer, data communication layer, computation layer, data management layer and data analysis and decision making layer. Besides reviewing the key technologies for implementing such networking architecture in detail, we conclude this survey by presenting future research directions of HDT.

References

[1]
Impact of COVID-19 on people’s livelihoods, their health and our food systems.” 2020. [Online]. Available: https://www.who.int/news/item/13-10-2020-impact-of-covid-19-on-people%27s-livelihoods-their-health-and-our-food-systems
[2]
[3]
W. H. Shrank, T. L. Rogstad, and N. Parekh, “Waste in the U.S. health care system: Estimated costs and potential for savings,” JAMA, vol. 322, no. 15, pp. 1501–1509, 2019.
[4]
B. Björnssonet al., “Digital twins to personalize medicine,” Genome Med., vol. 12, no. 1, pp. 1–4, 2020.
[5]
K. Paranjape, M. Schinkel, and P. Nanayakkara, “Short keynote paper: Mainstreaming personalized healthcare-transforming healthcare through new era of artificial intelligence,” IEEE J. Biomed. Health Inform., vol. 24, no. 7, pp. 1860–1863, Jul. 2020.
[6]
D. B. Neill, “Using artificial intelligence to improve hospital inpatient care,” IEEE Intell. Syst., vol. 28, no. 2, pp. 92–95, Mar./Apr. 2013.
[7]
E. VanDerHorn and S. Mahadevan, “Digital twin: Generalization, characterization and implementation,” Decis. Support Syst., vol. 145, Jun. 2021, Art. no.
[8]
J. Santos, T. Wauters, B. Volckaert, and F. De Turck, “Towards low-latency service delivery in a continuum of virtual resources: State-of-the-art and research directions,” IEEE Commun. Surveys Tuts., vol. 23, no. 4, pp. 2557–2589, 4th Quart., 2021.
[9]
K. Peng, H. Huang, M. Bilal, and X. Xu, “Distributed incentives for intelligent offloading and resource allocation in digital twin driven smart industry,” IEEE Trans. Ind. Informat., vol. 19, no. 3, pp. 3133–3143, Mar. 2023.
[10]
X. Liaoet al., “Cooperative ramp merging design and field implementation: A digital twin approach based on vehicle-to-cloud communication,” IEEE Trans. Intell. Transp. Syst., vol. 23, no. 5, pp. 4490–4500, May 2022.
[11]
H. V. Dang, M. Tatipamula, and H. X. Nguyen, “Cloud-based digital twinning for structural health monitoring using deep learning,” IEEE Trans. Ind. Informat., vol. 18, no. 6, pp. 3820–3830, Jun. 2022.
[12]
L. U. Khan, W. Saad, D. Niyato, Z. Han, and C. S. Hong, “Digital-twin-enabled 6G: Vision, architectural trends, and future directions,” IEEE Commun. Mag., vol. 60, no. 1, pp. 74–80, Jan. 2022.
[13]
S. D. Okegbile, J. Cai, C. Yi, and D. Niyato, “Human digital twin for personalized healthcare: Vision, architecture and future directions,” IEEE Netw., early access, Jul. 25, 2022. 10.1109/MNET.118.2200071.
[14]
W. Baicun, H. Zhou, G. Yang, X. Li, and H. Yang, “Human digital twin (HDT) driven human-cyber-physical systems: Key technologies and applications,” Chin. J. Mech. Eng., vol. 35, no. 1, p. 11, 2022.
[15]
( Geometric Solutions, Indianapolis, IN, USA). Siemens Healthineers Digital Twin of the Heart. (2000). [Online Video]. Available: https://www.youtube.com/watch?v=BqB1bwvv2-M
[16]
[17]
Computational Biomedicine. CompBioMed Virtual Humans Film. (2018). [Online Video]. Available: https://www.youtube.com/watch?v=1FvRSJ9W734
[18]
SIMULIA living heart: Advancing cardiovascular science with realistic simulation.” Dassault Systémes. 2022. [Online]. Available: https://www.3ds.com/products-services/simulia/solutions/life-sciences-healthcare/living-heart-human-model/
[19]
IBM digital twin.” IBM. 2022. [Online]. Available: https://www.ibm.com/ca-en/products/digital-twin-exchange
[20]
DigiTwin.” DigiTwin. 2022. [Online]. Available: https://www.mai.ai/digitwin/
[21]
R. Magargleet al., “A simulation-based digital twin for model-driven health monitoring and predictive maintenance of an automotive braking system,” in Proc. 12th Int. Modelica Conf., Prague, Czech Republic, May 2017, pp. 35–46.
[22]
Sim & Cure.” 2022. [Online]. Available: https://sim-and-cure.com/
[23]
Swedish digital twin consortium.” 2022. [Online]. Available: https://www.sdtc.se
[24]
European ecosystem for digital twins in healthcare.” DigitalEurope. 2023. [Online]. Available: https://www.digitaleurope.org/ecosystem-digital-twins-in-healthcare-edith/
[25]
Human digital twin.” SEMARX. 2023. [Online]. Available: https://www.semarx.com/human-twin
[26]
B. R. Barricelli, E. Casiraghi, and D. Fogli, “A survey on digital twin: Definitions, characteristics, applications, and design implications,” IEEE Access, vol. 7, pp. 167653–167671, 2019.
[27]
L. U. Khan, Z. Han, W. Saad, E. Hossain, M. Guizani, and C. S. Hong, “Digital twin of wireless systems: Overview, taxonomy, challenges, and opportunities,” IEEE Commun. Surveys Tuts., vol. 24, no. 4, pp. 2230–2254, 4th Quart., 2022.
[28]
F. Tao, H. Zhang, A. Liu, and A. Y. C. Nee, “Digital twin in industry: State-of-the-art,” IEEE Trans. Ind. Informat., vol. 15, no. 4, pp. 2405–2415, Apr. 2019.
[29]
A. Rasheed, O. San, and T. Kvamsdal, “Digital twin: Values, challenges and enablers from a modeling perspective,” IEEE Access, vol. 8, pp. 21980–22012, 2020.
[30]
C. Alcaraz and J. Lopez, “Digital twin: A comprehensive survey of security threats,” IEEE Commun. Surveys Tuts., vol. 24, no. 3, pp. 1475–1503, 3rd Quart., 2022.
[31]
S. Khan, T. Arslan, and T. Ratnarajah, “Digital twin perspective of fourth industrial and healthcare revolution,” IEEE Access, vol. 10, pp. 25732–25754, 2022.
[32]
R. Ferdousi, F. Laamarti, M. A. Hossain, C. Yang, and A. El Saddik, “Digital twins for well-being: An overview,” Digital Twin, vol. 1, no. 7, p. 7, 2022.
[33]
A. El Saddiket al., “Dtwins: A digital twins ecosystem for health and well-being,” IEEE COMSOC MMTC Commun. Front., vol. 14, no. 2, pp. 39–46, Mar. 2019.
[34]
A. El Saddik, F. Laamarti, and M. Alja’Afreh, “The potential of digital twins,” IEEE Instrum. Meas. Mag., vol. 24, no. 3, pp. 36–41, May 2021.
[35]
Y. Linet al., “Human digital twin: A survey,” 2022, arXiv:2212.05937.
[36]
M. Lauer-Schmaltz, P. Cash, J. Hansen, and A. Maier, “Designing human digital twins for behaviour-changing therapy and rehabilitation: A systematic review,” in Proc. Design Soc., vol. 2, 2022, pp. 1303–1312.
[37]
N. Barcelona. “Neurotwin.” 2019. [Online]. Available: https://www.neurotwin.eu
[38]
K. E. Batchet al., “Developing a cancer digital twin: Supervised metastases detection from consecutive structured radiology reports,” Front. Artif. Intell., vol. 5, Mar. 2022, Art. no.
[39]
G. Cedersund. “ISB Group.” 2023. [Online]. Available: https://liu.se/en/employee/gunce57/
[40]
M. E. Miller and E. Spatz, “A unified view of a human digital twin,” Human Intell. Syst. Integr., vol. 4, nos. 1–2, pp. 23–33, 2022.
[41]
A. De Benedictis, N. Mazzocca, A. Somma, and C. Strigaro, “Digital twins in healthcare: An architectural proposal and its application in a social distancing case study,” IEEE J. Biomed. Health Inform., early access, Sep. 9, 2022. 10.1109/JBHI.2022.3205506.
[42]
H. Pascual, X. M. Bruin, A. Alonso, and J. Cerdà, “A systematic review on human modeling: Digging into human digital twin implementations,” 2023, arXiv:2302.03593.
[43]
S. Sengan, K. Kumar, V. Subramaniyaswamy, and L. Ravi, “Cost-effective and efficient 3D human model creation and re-identification application for human digital twins,” Multimed. Tools. Appl., vol. 81, pp. 26839–26856, Aug. 2022.
[44]
M. Islam, R. Ferdousi, S. Rahman, and H. Y. Bushra, “Likelihood prediction of diabetes at early stage using data mining techniques,” in Proc. Comput. Vis. Mach. Intell. Med. Image Anal., 2020, pp. 113–125.
[45]
H. Ahmadi, A. Nag, Z. Khar, K. Sayrafian, and S. Rahardja, “Networked twins and twins of networks: An overview on the relationship between digital twins and 6G,” IEEE Commun. Mag., vol. 5, no. 4, pp. 154–160, Dec. 2021.
[46]
S. Hashimaet al., “On softwarization of intelligence in 6G networks for ultra-fast optimal policy selection: Challenges and opportunities,” IEEE Netw., early access, Feb. 18, 2022. 10.1109/MNET.103.2100587.
[47]
J. Zhang and Y. Tai, “Secure medical digital twin via human-centric interaction and cyber vulnerability resilience,” Connect. Sci., vol. 34, no. 1, pp. 895–910, 2022.
[48]
G. Minopoulos and K. E. Psannis, “Opportunities and challenges of tangible XR applications for 5G networks and beyond,” IEEE Consum. Electron. Mag., early access, Mar. 7, 2022. 10.1109/MCE.2022.3156305.
[49]
A. Nasrallahet al., “Ultra-low latency (ULL) networks: The IEEE TSN and IETF DetNet standards and related 5G ULL research,” IEEE Commun. Surveys Tuts., vol. 21, no. 1, pp. 88–145, 1st Quart., 2019.
[50]
A. Aijaz and M. Sooriyabandara, “The tactile Internet for industries: A review,” Proc. IEEE, vol. 107, no. 2, pp. 414–435, Feb. 2019.
[51]
H. Lonsdaleet al., “The perioperative human digital twin,” Anesthesia Analgesia, vol. 134, no. 4, pp. 885–892, 2022.
[52]
G. Sirigu, B. Carminati, and E. Ferrari, “Privacy and security issues for human digital twins,” in Proc. IEEE TPS-ISA, 2022, pp. 1–9.
[53]
W. Shengli, “Is human digital twin possible?,” Comput. Methods Programs Biomed., vol. 1, Jun. 2021, Art. no.
[54]
N. Y. Philip, J. J. P. C. Rodrigues, H. Wang, S. J. Fong, and J. Chen, “Internet of Things for in-home health monitoring systems: Current advances, challenges and future directions,” IEEE J. Sel. Areas Commun., vol. 39, no. 2, pp. 300–310, Feb. 2021.
[55]
M. Mirtchouk, C. Merck, and S. Kleinberg, “Automated estimation of food type and amount consumed from body-worn audio and motion sensors,” in Proc. ACM UbiComp, 2016, pp. 451–462.
[56]
R. Richer, T. Maiwald, C. Pasluosta, B. Hensel, and B. M. Eskofier, “Novel human computer interaction principles for cardiac feedback using Google glass and Android wear,” in Proc. IEEE BSN, 2015, pp. 1–6.
[57]
R. McNaney, I. Poliakov, J. Vines, M. Balaam, P. Zhang, and P. Olivier, “LApp: A speech loudness application for people with Parkinson’s on Google glass,” in Proc. ACM Conf. Human Factors Comput. Syst., 2015, pp. 497–500.
[58]
J. Kim, E. Cha, and J.-U. Park, “Recent advances in smart contact lenses,” Adv. Mater. Technol., vol. 5, no. 1, 2020, Art. no.
[59]
C. Posarelliet al., “Twenty-four-hour contact lens sensor monitoring of aqueous humor dynamics in surgically or medically treated glaucoma patients,” J. Ophthalmol., vol. 2019, Jan. 2019, Art. no.
[60]
L. Li, J. Yu, H. Cheng, and M. Peng, “A smart helmet-based PLS-BPNN error compensation model for infrared body temperature measurement of construction workers during COVID-19,” Mathematics, vol. 9, no. 21, p. 2808, 2021.
[61]
SmartCap Tech.” 2022. [Online]. Available: https://www.smartcaptech.com
[62]
T. Tazrin, Q. A. Rahman, M. M. Fouda, and Z. M. Fadlullah, “LiHEA: Migrating EEG analytics to ultra-edge IoT devices with logic-in-headbands,” IEEE Access, vol. 9, pp. 138834–138848, 2021.
[63]
R. De Luciaet al., “The in-ear region as a novel anatomical site for ECG signal detection: Validation study on healthy volunteers,” J. Interv. Card. Electrophysiol., vol. 60, no. 1, pp. 93–100, 2021.
[64]
R. Kinjoet al., “Development of a wearable mouth guard device for monitoring teeth clenching during exercise,” Sensors, vol. 21, no. 4, p. 1503, 2021.
[65]
DentiTrac.” 2022. [Online]. Available: https://www2.braebon.com/products/dentitrac
[66]
S. M. Ch, N. M. Abdul, S. Pendem, and K. B. KumarK, “WITHDRAWN: Smart jacket for health monitoring using LabVIEW,” Mater. Today Proc., to be published.
[67]
J. Albertoet al., “Fully untethered battery-free biomonitoring electronic tattoo with wireless energy harvesting,” Sci. Rep., vol. 10, no. 1, pp. 1–11, 2020.
[68]
S. V. Shinde and S. Sonavane, “Development of electronic tattoo for pulse rate monitoring: Materials perspective,” in Proc. AIP Conf., 2018, Art. no.
[69]
T. Terse-Thakooret al., “Thread-based multiplexed sensor patch for real-time sweat monitoring,” NPJ Flex. Electron., vol. 4, no. 1, pp. 1–10, 2020.
[70]
Z. A. Abro, Y.-F. Zhang, C.-Y. Hong, R. A. Lakho, and N.-L. Chen, “Development of a smart garment for monitoring body postures based on FBG and flex sensing technologies,” Sens. Actuator A Phys., vol. 272, pp. 153–160, Apr. 2018.
[71]
Z. Zhanget al., “A portable triboelectric nanogenerator for real-time respiration monitoring,” Nanoscale Res. Lett., vol. 14, no. 1, pp. 1–11, 2019.
[72]
C. He, J. Tan, X. Jian, G. Zhong, L. Cheng, and J. Lin, “A smart flexible vital signs and sleep monitoring belt based on MEMS triaxial accelerometer and pressure sensor,” IEEE Internet Things J., vol. 9, no. 15, pp. 14126–14136, Aug. 2022.
[73]
N. Huanget al., “Novel continuous respiratory rate monitoring using an armband wearable sensor,” in Proc. IEEE EMBC, 2021, pp. 7470–7475.
[74]
F. M. Musyoka, M. M. Thiga, and G. M. Muketha, “An assessment of suitable and affordable smart armband for preeclampsia management in antenatal care,” Int. J. Inf. Technol., vol. 3, no. 6, pp. 1–7, 2019.
[75]
G. Acar, O. Ozturk, and M. K. Yapici, “Wearable graphene nanotextile embedded smart armband for cardiac monitoring,” in Proc. IEEE Sensors, 2018, pp. 1–4.
[76]
P. Thamotharanet al., “Human digital twin for personalized elderly type 2 diabetes management,” J. Clin. Med., vol. 12, no. 6, p. 2094, 2023.
[77]
L. Uhlenberg, A. Derungs, and O. Amft, “Co-simulation of human digital twins and wearable inertial sensors to analyse gait event estimation,” Front. Bioeng. Biotechnol., vol. 11, Apr. 2023, Art. no.
[78]
X. Zhao, K. Guan, N. Zhang, and W. Ding, “Proposal of human digital twins system on behaviour recognition,” in Proc. ISAEECE, 2023, pp. 487–492.
[79]
Y. A. Qadri, A. Nauman, Y. B. Zikria, A. V. Vasilakos, and S. W. Kim, “The future of healthcare Internet of Things: A survey of emerging technologies,” IEEE Commun. Surveys Tuts., vol. 22, no. 2, pp. 1121–1167, 2nd Quart., 2020.
[80]
A. K. Pathak and C. Viphavakit, “VOC biomarker monitoring for diabetes through exhaled breath using Ag/P-TiO2 composite plasmonic sensor,” IEEE Sensors J., vol. 21, no. 20, pp. 22631–22637, Oct. 2021.
[81]
E. S. Bialecki and A. M. Di Bisceglie, “Diagnosis of hepatocellular carcinoma,” HPB, vol. 7, no. 1, pp. 26–34, 2005.
[82]
F. H. Juwono, R. Reine, W. Wong, Z. A. Sim, and L. Gopal, “Envisioning 6G molecular communication for IoBNT diagnostic systems,” in Proc. IEEE GECOST, 2021, pp. 1–5.
[83]
R. Mosayebi, A. Ahmadzadeh, W. Wicke, V. Jamali, R. Schober, and M. Nasiri-Kenari, “Early cancer detection in blood vessels using mobile nanosensors,” IEEE Trans. Nanobiosci., vol. 18, no. 2, pp. 103–116, Apr. 2019.
[84]
J. Chen, C. Yi, R. Wang, K. Zhu, and J. Cai, “Learning aided joint sensor activation and mobile charging vehicle scheduling for energy-efficient WRSN-based industrial IoT,” IEEE Trans. Veh. Technol., vol. 72, no. 4, pp. 5064–5078, Apr. 2023.
[85]
I. F. Akyildiz, M. Ghovanloo, U. Guler, T. Ozkaya-Ahmadov, A. F. Sarioglu, and B. D. Unluturk, “PANACEA: An Internet of bio-nanothings application for early detection and mitigation of infectious diseases,” IEEE Access, vol. 8, pp. 140512–140523, 2020.
[86]
Y. Chahibi and I. Balasingham, “An intra-body molecular communication networks framework for continuous health monitoring and diagnosis,” in Proc. IEEE EMBC, 2015, pp. 4077–4080.
[87]
X. Zhanget al., “Invasive and noninvasive means of measuring intracranial pressure: A review,” Physiol. Meas., vol. 38, no. 8, p. R143, 2017.
[88]
S.-K. Kanget al., “Bioresorbable silicon electronic sensors for the brain,” Nature, vol. 530, no. 7588, pp. 71–76, 2016.
[89]
A. P. Alivisatoset al., “Nanotools for neuroscience and brain activity mapping,” ACS Nano, vol. 7, no. 3, pp. 1850–1866, 2013.
[90]
I. F. Akyildiz, M. Pierobon, S. Balasubramaniam, and Y. Koucheryavy, “The Internet of bio-nano things,” IEEE Commun. Mag., vol. 53, no. 3, pp. 32–40, Mar. 2015.
[91]
P. Saariluoma, J. Cañas, and A. Karvonen, “Human digital twins and cognitive mimetic,” in Proc. IHIET, 2021, pp. 97–102.
[92]
K. Amara, O. Kerdjidj, and N. Ramzan, “Emotion recognition for affective human digital twin by means of virtual reality enabling technologies,” IEEE Access, vol. 11, pp. 74216–74227, 2023.
[93]
M. M. Rahmanet al., “Recognition of human emotions using EEG signals: A review,” Comput. Biol. Med., vol. 136, Sep. 2021, Art. no.
[94]
P. Nandwani and R. Verma, “A review on sentiment analysis and emotion detection from text,” Soc. Netw. Anal. Min., vol. 11, no. 1, pp. 1–19, 2021.
[95]
I. Priyadarshini, P. Mohanty, R. Kumar, R. Sharma, V. Puri, and P. K. Singh, “A study on the sentiments and psychology of Twitter users during COVID-19 lockdown period,” Multimed. Tools. Appl., vol. 81, no. 19, pp. 27009–27031, 2022.
[96]
D. Kalra, “Electronic health record standards,” Yearb. Med. Inform., vol. 15, no. 1, pp. 136–144, 2006.
[97]
S. Ghoseet al., “Human digital twin: Automated cell type distance computation and 3D atlas construction in multiplexed skin biopsies,” bioRxiv. 2022. [Online]. Available: https://doi.org/10.1101/2022.03.30.486438
[98]
G. Polettiet al., “Towards a digital twin of coronary stenting: A suitable and validated image-based approach for mimicking patient-specific coronary arteries,” Electronics, vol. 11, no. 3, p. 502, 2022.
[99]
Y. Taiet al., “Digital twin-enabled IoMT system for surgical simulation using rAC-GAN,” IEEE Internet Things J., vol. 9, no. 21, pp. 20918–20931, Nov. 2022.
[100]
H. Ahmadianet al., “Toward an artificial intelligence-assisted framework for reconstructing the digital twin of vertebra and predicting its fracture response,” Int. J. Numer. Methods Biomed., vol. 38, no. 6, 2022, Art. no.
[101]
K. Gilletteet al., “A framework for the generation of digital twins of cardiac electrophysiology from clinical 12-leads ECGs,” Med. Image. Anal., vol. 71, Jul. 2021, Art. no.
[102]
A. Allenet al., “A digital twins machine learning model for forecasting disease progression in stroke patients,” Appl. Sci., vol. 11, no. 12, p. 5576, 2021.
[103]
W. Guo, W. Ge, L. Cui, H. Li, and L. Kong, “An interpretable disease onset predictive model using crossover attention mechanism from electronic health records,” IEEE Access, vol. 7, pp. 134236–134244, 2019.
[104]
C. Dai, K. Zhu, and E. Hossain, “Multi-agent deep reinforcement learning for joint decoupled user association and trajectory design in full-duplex multi-UAV networks,” IEEE Trans. Mobile Comput., vol. 22, no. 10, pp. 6056–6070, Oct. 2023.
[105]
C. Yi and J. Cai, “Transmission management of delay-sensitive medical packets in beyond wireless body area networks: A queueing game approach,” IEEE Trans. Mobile Comput., vol. 17, no. 9, pp. 2209–2222, Sep. 2018.
[106]
C. Yi, Z. Zhao, J. Cai, R. L. de Faria, and G. M. Zhang, “Priority-aware pricing-based capacity sharing scheme for beyond-wireless body area networks,” Comput. Netw., vol. 98, pp. 29–43, Apr. 2016.
[107]
M. M. Alam, H. Malik, M. I. Khan, T. Pardy, A. Kuusik, and Y. Le Moullec, “A survey on the roles of communication technologies in IoT-based personalized healthcare applications,” IEEE Access, vol. 6, pp. 36611–36631, 2018.
[108]
H. Taleb, A. Nasser, G. Andrieux, N. Charara, and E. M. Cruz, “Wireless technologies, medical applications and future challenges in WBAN: A survey,” Wireless Netw., vol. 27, no. 8, pp. 5271–5295, 2021.
[109]
H. Habibzadeh, K. Dinesh, O. R. Shishvan, A. Boggio-Dandry, G. Sharma, and T. Soyata, “A survey of healthcare Internet of Things (HIoT): A clinical perspective,” IEEE Internet Things J., vol. 7, no. 1, pp. 53–71, Jan. 2020.
[110]
H. Pirayesh, P. K. Sangdeh, and H. Zeng, “Securing ZigBee communications against constant jamming attack using neural network,” IEEE Internet Things J., vol. 8, no. 6, pp. 4957–4968, Mar. 2021.
[111]
N. Farsad, H. B. Yilmaz, A. Eckford, C.-B. Chae, and W. Guo, “A comprehensive survey of recent advancements in molecular communication,” IEEE Commun. Surveys Tuts., vol. 18, no. 3, pp. 1887–1919, 3rd Quart., 2016.
[112]
T. Nakano, S. Kobayashi, T. Suda, Y. Okaie, Y. Hiraoka, and T. Haraguchi, “Externally controllable molecular communication,” IEEE J. Sel. Areas Commun., vol. 32, no. 12, pp. 2417–2431, Dec. 2014.
[113]
Z. Cheng, “Human digital twin with applications,” in Proc. DHM, vol. 7, 2022, p. 41.
[114]
C. Yi and J. Cai, “Delay-dependent priority-aware transmission scheduling for E-health networks: A mechanism design approach,” IEEE Trans. Veh. Technol., vol. 68, no. 7, pp. 6997–7010, Jul. 2019.
[115]
H. Xianget al., “Edge computing empowered tactile Internet for human digital twin: Visions and case study,” 2023, arXiv:2304.07454.
[116]
C. Fang, P. Zhang, and X. Qi, “Digital and intelligent liver surgery in the new era: Prospects and dilemmas,” EBioMedicine, vol. 41, pp. 693–701, Mar. 2019.
[117]
S. Senket al., “Healing hands: The tactile Internet in future tele-healthcare,” Sensors, vol. 22, no. 4, p. 1404, 2022.
[118]
A. E. Saddik, “Multimedia and the tactile Internet,” IEEE Multimedia, vol. 27, no. 1, pp. 5–7, Jan.–Mar. 2020.
[119]
V. Gokhale, K. Kroep, V. S. Rao, J. Verburg, and R. Yechangunja, “TIXT: An extensible testbed for tactile Internet communication,” IEEE Internet Things Mag., vol. 3, no. 1, pp. 32–37, Mar. 2020.
[120]
K. Polachan, T. Prabhakar, C. Singh, and F. A. Kuipers, “Towards an open testbed for tactile cyber physical systems,” in Proc. IEEE COMSNETS, 2019, pp. 375–382.
[121]
M. Al Ja’afreh, H. Adharni, and A. El Saddik, “Experimental QoS optimization for haptic communication over tactile Internet,” in Proc. IEEE HAVE, 2018, pp. 1–6.
[122]
N. Gholipoor, H. Saeedi, N. Mokari, and E. A. Jorswieck, “E2E QoS guarantee for the tactile Internet via joint NFV and radio resource allocation,” IEEE Trans. Netw. Service Manag., vol. 17, no. 3, pp. 1788–1804, Sep. 2020.
[123]
A. Samanta, B. Panigrahi, H. K. Rath, and S. Shailendra, “On low latency uplink scheduling for cellular haptic communication to support tactile Internet,” Wireless Pers. Commun., vol. 121, no. 3, pp. 1471–1488, 2021.
[124]
X. Luo, H.-H. Chen, and Q. Guo, “Semantic communications: Overview, open issues, and future research directions,” IEEE Wireless Commun., vol. 29, no. 1, pp. 210–219, Feb. 2022.
[125]
E. C. Strinati and S. Barbarossa, “6G networks: Beyond Shannon towards semantic and goal-oriented communications,” Comput. Netw., vol. 190, May 2021, Art. no.
[126]
C. Dai, K. Zhu, R. Wang, and B. Chen, “Contextual multi-armed bandit for cache-aware decoupled multiple association in UDNs: A deep learning approach,” IEEE Trans. Cogn. Commun. Netw., vol. 5, no. 4, pp. 1046–1059, Dec. 2019.
[127]
Y. Wanget al., “Performance optimization for semantic communications: An attention-based reinforcement learning approach,” IEEE J. Sel. Areas Commun., vol. 40, no. 9, pp. 2598–2613, Sep. 2022.
[128]
R. Ahlswede, “Identification via channels,” in Identification and Other Probabilistic Models: Rudolf Ahlswede’s Lectures on Information Theory 6. Cham, Switzerland: Springer, 2021, pp. 3–43.
[129]
R. Ferraraet al., “Implementation and experimental evaluation of Reed-Solomon identification,” in Proc. 27th Eur. Wireless Conf., 2022, pp. 1–6.
[130]
C. Von Lengerke, A. Hefele, J. A. Cabrera, O. Kosut, M. Reisslein, and F. H. Fitzek, “Identification codes: A topical review with design guidelines for practical systems,” IEEE Access, vol. 11, pp. 14961–14982, 2023.
[131]
H. Xie and Z. Qin, “A lite distributed semantic communication system for Internet of Things,” IEEE J. Sel. Areas Commun., vol. 39, no. 1, pp. 142–153, Jan. 2021.
[132]
H. Tonget al., “Federated learning for audio semantic communication,” Front. Commun. Netw., vol. 2, Sep. 2021, Art. no.
[133]
H. Xie, Z. Qin, G. Y. Li, and B.-H. Juang, “Deep learning enabled semantic communication systems,” IEEE Trans. Signal Process., vol. 69, pp. 2663–2675, 2021.
[134]
E. Bourtsoulatze, D. B. Kurka, and D. Gündüz, “Deep joint source-channel coding for wireless image transmission,” IEEE Trans. Cogn. Commun., vol. 5, no. 3, pp. 567–579, Sep. 2019.
[135]
C. Lin and S. Xiong, “Controllable face editing for video reconstruction in human digital twins,” Image Vis. Comput., vol. 125, Sep. 2022, Art. no.
[136]
Y. C. Hu, M. Patel, D. Sabella, N. Sprecher, and V. Young, “Mobile edge computing—A key technology towards 5G,” ETSI, Sophia Antipolis, France, White Paper, 2015.
[137]
C. Yi, J. Cai, and Z. Su, “A multi-user mobile computation offloading and transmission scheduling mechanism for delay-sensitive applications,” IEEE Trans. Mobile Comput., vol. 19, no. 1, pp. 29–43, Jan. 2020.
[138]
C. Yi, S. Huang, and J. Cai, “Joint resource allocation for device-to-device communication assisted fog computing,” IEEE Trans. Mobile Comput., vol. 20, no. 3, pp. 1076–1091, Mar. 2021.
[139]
R. Martinez-Velazquez, R. Gamez, and A. El Saddik, “Cardio twin: A digital twin of the human heart running on the edge,” in Proc. IEEE MeMeA, 2019, pp. 1–6.
[140]
R. G. Díaz, F. Laamarti, and A. El Saddik, “DTCoach: Your digital twin coach on the edge during COVID-19 and beyond,” IEEE Instrum. Meas. Mag., vol. 24, no. 6, pp. 22–28, Sep. 2021.
[141]
S. D. Okegbile and J. Cai, “Edge-assisted human-to-virtual twin connectivity scheme for human digital twin frameworks,” in Proc. IEEE VTC, 2022, pp. 1–6.
[142]
P. Pace, G. Aloi, R. Gravina, G. Caliciuri, G. Fortino, and A. Liotta, “An edge-based architecture to support efficient applications for healthcare industry 4.0,” IEEE Trans. Ind. Informat., vol. 15, no. 1, pp. 481–489, Jan. 2019.
[143]
H. N. Qureshi, M. Manalastas, A. Ijaz, A. Imran, Y. Liu, and M. O. Al Kalaa, “Communication requirements in 5G-enabled healthcare applications: Review and considerations,” Healthcare, vol. 10, no. 2, p. 293, 2022.
[144]
J. Tan, X. Sha, B. Dai, and T. Lu, “Wireless technology and protocol for IIoT and digital twins,” in Proc. ITU Kaleidoscope Ind.-Driven Digit. Transformation (ITU K), 2020, pp. 1–8.
[145]
K. Peng, P. Liu, M. Bilal, X. Xu, and E. Prezioso, “Mobility and privacy-aware offloading of AR applications for healthcare cyber-physical systems in edge computing,” IEEE Trans. Netw. Sci. Eng., early access, Jun. 24, 2022. 10.1109/TNSE.2022.3185092.
[146]
C. Yi, J. Cai, T. Zhang, K. Zhu, B. Chen, and Q. Wu, “Workload re-allocation for edge computing with server collaboration: A cooperative queueing game approach,” IEEE Trans. Mobile Comput., vol. 22, no. 5, pp. 3095–3111, May 2023.
[147]
C. Yi, J. Cai, K. Zhu, and R. Wang, “A queueing game based management framework for fog computing with strategic computing speed control,” IEEE Trans. Mobile Comput., vol. 21, no. 5, pp. 1537–1551, May 2022.
[148]
K. Peng, H. Huang, P. Liu, X. Xu, and V. C. M. Leung, “Joint optimization of energy conservation and privacy preservation for intelligent task offloading in MEC-enabled smart cities,” IEEE Trans. Green Commun. Netw., vol. 6, no. 3, pp. 1671–1682, Sep. 2022.
[149]
C. Yi and J. Cai, “A truthful mechanism for scheduling delay-constrained wireless transmissions in IoT-based healthcare networks,” IEEE Trans. Wireless Commun., vol. 18, no. 2, pp. 912–925, Feb. 2019.
[150]
P. K. Bishoyi and S. Misra, “Priority-aware cooperative data uploading in body-to-body networks for healthcare IoT,” IEEE Internet Things J., vol. 9, no. 12, pp. 10319–10326, Jun. 2022.
[151]
W. Lu, Q. Zheng, N. Xu, and J. Feng, “The human digital twin brain in the resting state and in action,” 2022, arXiv:2211.15963.
[152]
T. Taleb, K. Samdanis, B. Mada, H. Flinck, S. Dutta, and D. Sabella, “On multi-access edge computing: A survey of the emerging 5G network edge cloud architecture and orchestration,” IEEE Commun. Surveys Tuts., vol. 19, no. 3, pp. 1657–1681, 3rd Quart., 2017.
[153]
Y. Shi, C. Yi, B. Chen, C. Yang, K. Zhu, and J. Cai, “Joint online optimization of data sampling rate and preprocessing mode for edge–cloud collaboration-enabled industrial IoT,” IEEE Internet Things J., vol. 9, no. 17, pp. 16402–16417, Sep. 2022.
[154]
K. Peng, H. Huang, B. Zhao, A. Jolfaei, X. Xu, and M. Bilal, “Intelligent computation offloading and resource allocation in IIoT with end-edge-cloud computing using NSGA-III,” IEEE Trans. Netw. Sci. Eng., early access, Mar. 8, 2022. 10.1109/TNSE.2022.3155490.
[155]
S. Ghosh, J. Das, S. K. Ghosh, and R. Buyya, “CLAWER: Context-aware cloud-fog based workflow management framework for health emergency services,” in Proc. IEEE/ACM CCGRID, 2020, pp. 810–817.
[156]
X. Tu, K. Zhu, N. C. Luong, D. Niyato, Y. Zhang, and J. Li, “Incentive mechanisms for federated learning: From economic and game theoretic perspective,” IEEE Trans. Cogn. Commun. Netw., vol. 8, no. 3, pp. 1566–1593, Sep. 2022.
[157]
X. Tu and K. Zhu, “Learning-based multi-objective resource allocation for over-the-air federated learning,” in Proc. IEEE GLOBECOM, 2022, pp. 3065–3070.
[158]
S. Okegbile, J. Cai, H. Zheng, J. Chen, and C. Yi, “Differentially private federated multi-task learning framework for enhancing human-to-virtual connectivity in human digital twin,” IEEE J. Sel. Areas Commun., submitted to publication.
[159]
D. Gupta, O. Kayode, S. Bhatt, M. Gupta, and A. S. Tosun, “Hierarchical federated learning based anomaly detection using digital twins for smart healthcare,” in Proc. IEEE CIC, 2021, pp. 16–25.
[160]
Q. Wu, X. Chen, Z. Zhou, and J. Zhang, “FedHome: Cloud-edge based personalized federated learning for in-home health monitoring,” IEEE Trans. Mobile Comput., vol. 21, no. 8, pp. 2818–2832, Aug. 2022.
[161]
H.-T. Chiang, Y.-Y. Hsieh, S.-W. Fu, K.-H. Hung, Y. Tsao, and S.-Y. Chien, “Noise reduction in ECG signals using fully convolutional denoising autoencoders,” IEEE Access, vol. 7, pp. 60806–60813, 2019.
[162]
Z. Xu, F. R. Sheykhahmad, N. Ghadimi, and N. Razmjooy, “Computer-aided diagnosis of skin cancer based on soft computing techniques,” Open Med., vol. 15, no. 1, pp. 860–871, 2020.
[163]
S. Nasrin, M. Z. Alom, R. Burada, T. M. Taha, and V. K. Asari, “Medical image denoising with recurrent residual U-Net (R2U-Net) base auto-encoder,” in Proc. IEEE NAECON, 2019, pp. 345–350.
[164]
A. Suresh, R. Kumar, and R. Varatharajan, “Health care data analysis using evolutionary algorithm,” J. Supercomput., vol. 76, no. 6, pp. 4262–4271, 2020.
[165]
N. L. Fitriyani, M. Syafrudin, G. Alfian, and J. Rhee, “HDPM: An effective heart disease prediction model for a clinical decision support system,” IEEE Access, vol. 8, pp. 133034–133050, 2020.
[166]
B. R. Barricelli, E. Casiraghi, J. Gliozzo, A. Petrini, and S. Valtolina, “Human digital twin for fitness management,” IEEE Access, vol. 8, pp. 26637–26664, 2020.
[167]
J. Zhang, L. Li, G. Lin, D. Fang, Y. Tai, and J. Huang, “Cyber resilience in healthcare digital twin on lung cancer,” IEEE Access, vol. 8, pp. 201900–201913, 2020.
[168]
F. Biessmann, D. Salinas, S. Schelter, P. Schmidt, and D. Lange, “‘Deep’ learning for missing value imputation in tables with non-numerical data,” in Proc. ACM CIKM, 2018, pp. 2017–2025.
[169]
S. Phung, A. Kumar, and J. Kim, “A deep learning technique for imputing missing healthcare data,” in Proc. IEEE EMBC, 2019, pp. 6513–6516.
[170]
A. Jović, K. Brkić, and N. Bogunović, “A review of feature selection methods with applications,” in Proc. MIPRO, 2015, pp. 1200–1205.
[171]
M. Alirezanejad, R. Enayatifar, H. Motameni, and H. Nematzadeh, “Heuristic filter feature selection methods for medical datasets,” Genomics, vol. 112, no. 2, pp. 1173–1181, 2020.
[172]
M. Yuan, Z. Yang, and G. Ji, “Partial maximum correlation information: A new feature selection method for microarray data classification,” Neurocomputing, vol. 323, pp. 231–243, Jan. 2019.
[173]
B. Remeseiro and V. Bolon-Canedo, “A review of feature selection methods in medical applications,” Comput. Biol. Med., vol. 112, Sep. 2019, Art. no.
[174]
N. Almugren and H. Alshamlan, “FF-SVM: New firefly-based gene selection algorithm for microarray cancer classification,” in Proc. IEEE CIBCB, 2019, pp. 1–6.
[175]
T. M. Le, T. M. Vo, T. N. Pham, and S. V. T. Dao, “A novel wrapper–based feature selection for early diabetes prediction enhanced with a metaheuristic,” IEEE Access, vol. 9, pp. 7869–7884, 2021.
[176]
C. Kang, Y. Huo, L. Xin, B. Tian, and B. Yu, “Feature selection and tumor classification for microarray data using relaxed lasso and generalized multi-class support vector machine,” J. Theor. Biol., vol. 463, pp. 77–91, Feb. 2019.
[177]
Z. Li, W. Xie, and T. Liu, “Efficient feature selection and classification for microarray data,” PLoS One, vol. 13, no. 8, 2018, Art. no.
[178]
R. M. S. Priyaet al., “An effective feature engineering for DNN using hybrid PCA-GWO for intrusion detection in IoMT architecture,” Comput. Commun., vol. 160, pp. 139–149, Jul. 2020.
[179]
G. T. Reddyet al., “Analysis of dimensionality reduction techniques on big data,” IEEE Access, vol. 8, pp. 54776–54788, 2020.
[180]
C. Hurr, C. Li, and H. Li, “Feature extraction and recognition of human physiological signals based on the convolutional neural network,” Mobile Inf. Syst., vol. 2022, Jul. 2022, Art. no.
[181]
W. Liuet al., “Research on medical data feature extraction and intelligent recognition technology based on convolutional neural network,” IEEE Access, vol. 7, pp. 150157–150167, 2019.
[182]
A. Yang, X. Yang, W. Wu, H. Liu, and Y. Zhuansun, “Research on feature extraction of tumor image based on convolutional neural network,” IEEE Access, vol. 7, pp. 24204–24213, 2019.
[183]
D. Yang, H. R. Karimi, O. Kaynak, and S. Yin, “Developments of digital twin technologies in industrial, smart city and healthcare sectors: A survey,” Complex Eng. Syst., vol. 1, no. 1, p. 3, 2021.
[184]
R. Dautov, S. Distefano, and R. Buyya, “Hierarchical data fusion for smart healthcare,” J. Big Data, vol. 6, no. 1, pp. 1–23, 2019.
[185]
K.-H. Thung, P.-T. Yap, and D. Shen, “Multi-stage diagnosis of Alzheimer’s disease with incomplete multimodal data via multi-task deep learning,” in Proc. Deep Learn. Med. Image Anal. Multimodal Learn. Clin. Decis. Support, 2017, pp. 160–168.
[186]
T. Casian, B. Nagy, B. Kovács, D. L. Galata, E. Hirsch, and A. Farkas, “Challenges and opportunities of implementing data fusion in process analytical technology—A review,” Molecules, vol. 27, no. 15, p. 4846, 2022.
[187]
F. Aliet al., “A smart healthcare monitoring system for heart disease prediction based on ensemble deep learning and feature fusion,” Inf. Fusion, vol. 63, pp. 208–222, Nov. 2020.
[188]
Y. Yooet al., “Deep learning of brain lesion patterns and user-defined clinical and MRI features for predicting conversion to multiple sclerosis from clinically isolated syndrome,” Comput. Methods Biomech. Biomed. Eng. Imaging Vis., vol. 7, no. 3, pp. 250–259, 2019.
[189]
S. Qiu, G. H. Chang, M. Panagia, D. M. Gopal, R. Au, and V. B. Kolachalama, “Fusion of deep learning models of MRI scans, mini–mental state examination, and logical memory test enhances diagnosis of mild cognitive impairment,” Alzheimer’s Dementia, vol. 10, pp. 737–749, Sep. 2018.
[190]
F. Lalmi and L. Adala, “Big data for healthcare: Opportunities and challenges,” in The Fourth Industrial Revolution: Implementation of Artificial Intelligence for Growing Business Success. Cham, Switzerland: Springer, 2021, pp. 217–229.
[191]
K. Shvachko, H. Kuang, S. Radia, and R. Chansler, “The Hadoop distributed file system,” in Proc. IEEE MSST, 2010, pp. 1–10.
[192]
M. D. Babu, K. Ramesh, P. Renjith, and B. Prabha, “An efficient healthcare medication system with clustering algorithm using Euclidean distance adjoining data lake,” in Proc. ACCAI, 2022, pp. 1–5.
[193]
Y. K. Gupta, “Aspect of big data in medical imaging to extract the hidden information using HIPI in HDFS environment,” in Advancement of Machine Intelligence in Interactive Medical Image Analysis. Singapore: Springer, 2020, pp. 19–40.
[194]
K. Addakiri, H. Khallouki, and M. Bahaj, “Healthcare data storage based on HBase,” in Proc. AI2SD, 2019, pp. 199–205.
[195]
S. Thota, R. P. R. Induri, and R. Kune, “Split key management framework for open stack swift object storage cloud,” CSI Trans. ICT, vol. 5, no. 4, pp. 397–406, 2017.
[196]
S. B. Akintoye, A. Bagula, and O. E. Isafiade, “Towards fog-based cyber-healthcare data storage security and availability,” in Proc. IST-Africa Conf., 2018, pp. 1–16.
[197]
G. Kambourakis, C. Kolias, D. Geneiatakis, G. Karopoulos, G. M. Makrakis, and I. Kounelis, “A state-of-the-art review on the security of mainstream IoT wireless PAN protocol stacks,” Symmetry, vol. 12, no. 4, p. 579, 2020.
[198]
E. Lee, Y.-D. Seo, S.-R. Oh, and Y.-G. Kim, “A survey on standards for interoperability and security in the Internet of Things,” IEEE Commun. Surveys Tuts., vol. 23, no. 2, pp. 1020–1047, 2nd Quart., 2021.
[199]
M. R. Ghori, T.-C. Wan, and G. C. Sodhy, “Bluetooth low energy mesh networks: Survey of communication and security protocols,” Sensors, vol. 20, no. 12, p. 3590, 2020.
[200]
J. Zhang, S. Wang, and S. Chen, “Reconstruction enhanced multi-view contrastive learning for anomaly detection on attributed networks,” in Proc. IJCAI, 2022, pp. 2376–2382.
[201]
H. Chen, C. Meng, Z. Shan, Z. Fu, and B. K. Bhargava, “A novel low-rate denial of service attack detection approach in ZigBee wireless sensor network by combining Hilbert-Huang transformation and trust evaluation,” IEEE Access, vol. 7, pp. 32853–32866, 2019.
[202]
A. Ramos, R. T. P. Milfont, R. H. Filho, and J. J. P. C. Rodrigues, “Enabling online quantitative security analysis in 6LoWPAN networks,” IEEE Internet Things J., vol. 6, no. 3, pp. 5631–5638, Jun. 2019.
[203]
W. Schneble and G. Thamilarasu, “Attack detection using federated learning in medical cyber-physical systems,” in Proc. ICCCN, 2019, pp. 1–8.
[204]
G. Thamilarasu, A. Odesile, and A. Hoang, “An intrusion detection system for Internet of Medical Things,” IEEE Access, vol. 8, pp. 181560–181576, 2020.
[205]
N. Sun, J. Zhang, P. Rimba, S. Gao, L. Y. Zhang, and Y. Xiang, “Data-driven cybersecurity incident prediction: A survey,” IEEE Commun. Surveys Tuts., vol. 21, no. 2, pp. 1744–1772, 2nd Quart., 2019.
[206]
Y. Lee, H. Kwon, S.-H. Choi, S.-H. Lim, S. H. Baek, and K.-W. Park, “Instruction2vec: Efficient preprocessor of assembly code to detect software weakness with CNN,” Appl. Sci., vol. 9, no. 19, p. 4086, 2019.
[207]
Y. Zhou, S. Liu, J. Siow, X. Du, and Y. Liu, “Devign: Effective vulnerability identification by learning comprehensive program semantics via graph neural networks,” in Proc. Adv. Neural Inf. Process. Syst., vol. 32, 2019, pp. 1–11.
[208]
R. R. K. Chaudhary and K. Chatterjee, “An efficient lightweight cryptographic technique for IoT based e-healthcare system,” in Proc. SPIN, 2020, pp. 991–995.
[209]
H. Noura, A. Chehab, and R. Couturier, “Lightweight dynamic key-dependent and flexible cipher scheme for IoT devices,” in Proc. IEEE WCNC, 2019, pp. 1–8.
[210]
Y. Zheng, R. Lu, Y. Guan, S. Zhang, and J. Shao, “Towards private similarity query based healthcare monitoring over digital twin cloud platform,” in Proc. IEEE/ACM IWQOS, 2021, pp. 1–10.
[211]
L. Zhang, J. Xu, P. Vijayakumar, P. K. Sharma, and U. Ghosh, “Homomorphic encryption-based privacy-preserving federated learning in IoT-enabled healthcare system,” IEEE Trans. Netw. Sci. Eng., early access, Jun. 30, 2022. 10.1109/TNSE.2022.3185327.
[212]
M. U. Shaikh, W. A. Wan Adnan, and S. A. Ahmad, “Sensitivity and positive prediction of secured electrocardiograph (ECG) transmission using fully homomorphic encryption technique (FHE),” in Proc. IEEE IECBES, 2021, pp. 292–297.
[213]
L. Mirtskhulava, M. Iavich, M. Razmadze, and N. Gulua, “Securing medical data in 5G and 6G via multichain blockchain technology using post-quantum signatures,” in Proc. IEEE Int. Conf. Inf. Telecommun. Technol. Radio Electron., 2021, pp. 72–75.
[214]
G. Xuet al., “PPSEB: A postquantum public-key searchable encryption scheme on blockchain for E-healthcare scenarios,” Security Commun. Netw., vol. 2022, Mar. 2022, Art. no.
[215]
A. Majeed, “Attribute-centric anonymization scheme for improving user privacy and utility of publishing e-health data,” J. King Saud Univ. Comput. Inf. Sci., vol. 31, no. 4, pp. 426–435, 2019.
[216]
A. Aminifar, F. Rabbi, V. K. I. Pun, and Y. Lamo, “Diversity-aware anonymization for structured health data,” in Proc. IEEE EMBC, 2021, pp. 2148–2154.
[217]
C. Angulo, L. Gonzalez-Abril, C. Raya, and J. A. Ortega, “A proposal to evolving towards digital twins in healthcare,” in Proc. IWBBIO, 2020, pp. 418–426.
[218]
E. Piacentino and C. Angulo, “Generating fake data using GANs for anonymizing healthcare data,” in Proc. IWBBIO, 2020, pp. 406–417.
[219]
M. Ali, F. Naeem, M. Tariq, and G. Kaddoum, “Federated learning for privacy preservation in smart healthcare systems: A comprehensive survey,” IEEE J. Biomed. Health Inform., vol. 27, no. 2, pp. 778–789, Feb. 2023.
[220]
S. D. Okegbile, J. Cai, and A. S. Alfa, “Practical Byzantine fault tolerance-enhanced blockchain-enabled data sharing system: Latency and age of data package analysis,” IEEE Trans. Mobile Comput., early access, Nov. 18, 2022. 10.1109/TMC.2022.3223306.
[221]
S. D. Okegbile, J. Cai, and A. S. Alfa, “Performance analysis of blockchain-enabled data-sharing scheme in cloud-edge computing-based IoT networks,” IEEE Internet Things J., vol. 9, no. 21, pp. 21520–21536, Nov. 2022.
[222]
J. Jiang, Y. Zhang, Y. Zhu, X. Dong, L. Wang, and Y. Xiang, “DCIV: Decentralized cross-chain data integrity verification with blockchain,” J. King Saud Univ. Comput. Inf. Sci., vol. 34, no. 10, pp. 7988–7999, 2022.
[223]
Y. Zhang, J. Jiang, X. Dong, L. Wang, and Y. Xiang, “BeDCV: Blockchain-enabled decentralized consistency verification for cross-chain calculation,” IEEE Trans. Cloud Comput., early access, Aug. 8, 2022. 10.1109/TCC.2022.3196937.
[224]
Y. Zhang, J. Zhao, J. Jiang, Y. Zhu, L. Wang, and Y. Xiang, “Recording behaviors of artificial intelligence in blockchains,” IEEE Trans. Artif. Intell., early access, Oct. 11, 2022. 10.1109/TAI.2022.3213531.
[225]
H. Zhao, Y. Zhang, Y. Peng, and R. Xu, “Lightweight backup and efficient recovery scheme for health blockchain keys,” in Proc. IEEE ISADS, 2017, pp. 229–234.
[226]
X. Yue, H. Wang, D. Jin, M. Li, and W. Jiang, “Healthcare data gateways: Found healthcare intelligence on blockchain with novel privacy risk control,” J. Med. Syst., vol. 40, no. 10, pp. 1–8, Aug. 2016.
[227]
L. Zhang, M. Peng, W. Wang, Y. Su, S. Cui, and S. Kim, “Secure and efficient data storage and sharing scheme based on double blockchain,” Comput., Materials Continua, vol. 66, no. 1, pp. 500–515, 2021.
[228]
D. C. Nguyen, P. N. Pathirana, M. Ding, and A. Seneviratne, “BEdgeHealth: A decentralized architecture for edge-based IoMT networks using blockchain,” IEEE Internet Things J., vol. 8, no. 14, pp. 11743–11757, Jul. 2021.
[229]
J. Liu, X. Li, L. Ye, H. Zhang, X. Du, and M. Guizani, “BPDS: A blockchain based privacy-preserving data sharing for electronic medical records,” in Proc. IEEE GLOBECOM, 2018, pp. 1–6.
[230]
D. Mourtziset al., “A smart IoT platform for oncology patient diagnosis based on AI: Towards the human digital twin,” Procedia CIRP, vol. 104, pp. 1686–1691, Jan. 2021.
[231]
N. K. Chakshu, J. Carson, I. Sazonov, and P. Nithiarasu, “A semi-active human digital twin model for detecting severity of carotid stenoses from head vibration—A coupled computational mechanics and computer vision method,” Int. J. Numer. Method Biomed. Eng., vol. 35, no. 5, 2019, Art. no.
[232]
S. Gochhait and A. Bende, “Leveraging digital twin technology in the healthcare industry—A machine learning based approach,” Eur. J. Mol. Clin. Med., vol. 7, no. 6, pp. 2547–2557, 2020.
[233]
H. Elayan, M. Aloqaily, and M. Guizani, “Digital twin for intelligent context-aware IoT healthcare systems,” IEEE Internet Things J., vol. 8, no. 23, pp. 16749–16757, Dec. 2021.
[234]
N. K. Chakshu, I. Sazonov, and P. Nithiarasu, “Towards enabling a cardiovascular digital twin for human systemic circulation using inverse analysis,” Biomech. Model. Mechanobiol., vol. 20, no. 2, pp. 449–465, 2021.
[235]
X.-H. Liet al., “A survey of data-driven and knowledge-aware eXplainable AI,” IEEE Trans. Knowl. Data Eng., vol. 34, no. 1, pp. 29–49, Jan. 2022.
[236]
V. Pitroda, M. M. Fouda, and Z. M. Fadlullah, “An explainable AI model for interpretable lung disease classification,” in Proc. IEEE IoTaIS, 2021, pp. 98–103.
[237]
A. Lalet al., “Development and verification of a digital twin patient model to predict specific treatment response during the first 24 hours of sepsis,” Crit. Care Explor., vol. 2, no. 11, 2020, Art. no.
[238]
E. Tardiniet al., “Optimal policy determination in sequential systemic and locoregional therapy of oropharyngeal squamous carcinomas: A patient-physician digital twin dyad with deep q-learning for treatment selection,” medRxiv. 2021. [Online]. Available: https://doi.org/10.1101/2021.04.07.21255092
[239]
T. Liet al., “Applications of multi-agent reinforcement learning in future Internet: A comprehensive survey,” IEEE Commun. Surveys Tuts., vol. 24, no. 2, pp. 1240–1279, 2nd Quart., 2022.
[240]
E. S. Donkor, “Stroke in the century: A snapshot of the burden, epidemiology, and quality of life,” Stroke Res. Treat., vol. 2018, 2018, Art. no.
[241]
I. Voigt, H. Inojosa, A. Dillenseger, R. Haase, K. Akgün, and T. Ziemssen, “Digital twins for multiple sclerosis,” Front. Immunol., vol. 12, May 2021, Art. no.
[242]
C. K. Fisher, A. M. Smith, and J. R. Walsh, “Machine learning for comprehensive forecasting of Alzheimer’s disease progression,” Sci. Rep., vol. 9, no. 1, pp. 1–14, 2019.
[243]
P. Barbiero, R. Viñas Torné, and P. Lió, “Graph representation forecasting of patient’s medical conditions: Toward a digital twin,” Front. Genet., vol. 12, Sep. 2021, Art. no.
[244]
P. D. Radford, L. F. Derbyshire, J. Shalhoub, and J. E. F. Fitzgerald, “Publication of surgeon specific outcome data: A review of implementation, controversies and the potential impact on surgical training,” Int. J. Surg., vol. 13, pp. 211–216, Jan. 2015.
[245]
J. Chenet al., “A revolution of personalized healthcare: Enabling human digital twin with mobile AIGC,” 2023, arXiv:2307.12115.
[246]
Y.-C. Jhenget al., “A novel machine learning-based algorithm to identify and classify lesions and anatomical landmarks in colonoscopy images,” Surg. Endosc., vol. 36, no. 1, pp. 640–650, 2022.
[247]
E. Rubinsteinet al., “Unsupervised tumor detection in dynamic PET/CT imaging of the prostate,” Med. Image Anal., vol. 55, pp. 27–40, Jul. 2019.
[248]
N. Torosdagli, D. K. Liberton, P. Verma, M. Sincan, J. S. Lee, and U. Bagci, “Deep geodesic learning for segmentation and anatomical landmarking,” IEEE Trans. Med. Imag., vol. 38, no. 4, pp. 919–931, Apr. 2019.
[249]
S. Lee, S. Woo, J. Yu, J. Seo, J. Lee, and C. Lee, “Automated CNN-based tooth segmentation in cone-beam CT for dental implant planning,” IEEE Access, vol. 8, pp. 50507–50518, 2020.
[250]
X. Li, Z. Gong, H. Yin, H. Zhang, Z. Wang, and L. Zhuo, “A 3D deep supervised densely network for small organs of human temporal bone segmentation in CT images,” Neural Netw., vol. 124, pp. 75–85, Apr. 2020.
[251]
P. Riedel, M. Riesner, K. Wendt, and U. Aßmann, “Data-driven digital twins in surgery utilizing augmented reality and machine learning,” in Proc. IEEE ICC WKSHPS, 2022, pp. 580–585.
[252]
X.-Y. Zhou, Y. Guo, M. Shen, and G.-Z. Yang, “Application of artificial intelligence in surgery,” Front. Med., vol. 14, no. 4, pp. 417–430, 2020.
[253]
C. Shin, P. W. Ferguson, S. A. Pedram, J. Ma, E. P. Dutson, and J. Rosen, “Autonomous tissue manipulation via surgical robot using learning based model predictive control,” in Proc. ICRA, 2019, pp. 3875–3881.
[254]
J. Fan, P. Zheng, and C. K. Lee, “A vision-based human digital twin modelling approach for adaptive human-robot collaboration,” J. Manuf. Sci. Eng., vol. 145, no. 12, 2023, Art. no.
[255]
P. Li, X. Hou, L. Wei, G. Song, and X. Duan, “Efficient and low-cost deep-learning based gaze estimator for surgical robot control,” in Proc. IEEE RCAR, 2018, pp. 58–63.
[256]
K. Fujii, G. Gras, A. Salerno, and G.-Z. Yang, “Gaze gesture based human robot interaction for laparoscopic surgery,” Med. Image Anal., vol. 44, pp. 196–214, Feb. 2018.
[257]
J.-L. Ren, Y.-H. Chien, E.-Y. Chia, L.-C. Fu, and J.-S. Lai, “Deep learning based motion prediction for exoskeleton robot control in upper limb rehabilitation,” in Proc. ICRA, 2019, pp. 5076–5082.
[258]
V. Alekseyev, A. Vizgirda, D. Nefedyev, and A. Tsareva, “Measuring systems for monitoring the human state: Human digital twins based on a kinematic portrait,” in Proc. J. Phys. Conf., 2021, Art. no.
[259]
M. Ebnali, N. Ahmadi, E. Nabiyouni, and H. Karimi, “AI-powered human digital twins in virtual therapeutic sessions,” in Proc. Int. Symp. Human Factors Ergo. Health Care, vol. 12, 2023, pp. 1–4.
[260]
M. H. Lee, D. P. Siewiorek, A. Smailagic, A. Bernardino, and S. Bermúdez i Badia, “Co-design and evaluation of an intelligent decision support system for stroke rehabilitation assessment,” Proc. ACM Human Comput. Interact., vol. 4, no. CSCW2, pp. 1–27, 2020.
[261]
M. H. Lee, D. P. Siewiorek, A. Smailagic, A. Bernardino, and S. Bermúdez i Badia, “A human-AI collaborative approach for clinical decision making on rehabilitation assessment,” in Proc. CHI, 2021, pp. 1–14.
[262]
K. Yaoet al., “Encoding of tactile information in hand via skin-integrated wireless haptic interface,” Nat. Mach. Intell., vol. 4, no. 10, pp. 893–903, 2022.
[263]
S. J. Pan and Q. Yang, “A survey on transfer learning,” IEEE Trans. Knowl. Data Eng., vol. 22, no. 10, pp. 1345–1359, Oct. 2010.
[264]
C. Finn, P. Abbeel, and S. Levine, “Model-agnostic meta-learning for fast adaptation of deep networks,” in Proc. ICML, 2017, pp. 1126–1135.
[265]
K. Mallingeret al., “Potential threats of human digital twins for digital sovereignty and the sustainable development goals,” UN IATT, New York, NY, USA, Rep., 2021. [Online]. Available: https://sdgs.un.org/sites/default/files/2021-05/IATT%20report%20on%20emerging%20techs%202021.pdf
[266]
T. N. Nguyen, “Toward human digital twins for cybersecurity simulations on the metaverse: Ontological and network science approach,” JMIRx Med, vol. 3, no. 2, 2022, Art. no.

Cited By

View all
  • (2024)COPSA: a computation offloading strategy based on PPO algorithm and self-attention mechanism in MEC-empowered smart factoriesJournal of Cloud Computing: Advances, Systems and Applications10.1186/s13677-024-00714-913:1Online publication date: 5-Nov-2024

Index Terms

  1. Networking Architecture and Key Supporting Technologies for Human Digital Twin in Personalized Healthcare: A Comprehensive Survey
          Index terms have been assigned to the content through auto-classification.

          Recommendations

          Comments

          Please enable JavaScript to view thecomments powered by Disqus.

          Information & Contributors

          Information

          Published In

          cover image IEEE Communications Surveys & Tutorials
          IEEE Communications Surveys & Tutorials  Volume 26, Issue 1
          Firstquarter 2024
          746 pages

          Publisher

          IEEE Press

          Publication History

          Published: 04 September 2023

          Qualifiers

          • Research-article

          Contributors

          Other Metrics

          Bibliometrics & Citations

          Bibliometrics

          Article Metrics

          • Downloads (Last 12 months)0
          • Downloads (Last 6 weeks)0
          Reflects downloads up to 22 Dec 2024

          Other Metrics

          Citations

          Cited By

          View all
          • (2024)COPSA: a computation offloading strategy based on PPO algorithm and self-attention mechanism in MEC-empowered smart factoriesJournal of Cloud Computing: Advances, Systems and Applications10.1186/s13677-024-00714-913:1Online publication date: 5-Nov-2024

          View Options

          View options

          Media

          Figures

          Other

          Tables

          Share

          Share

          Share this Publication link

          Share on social media