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References

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1. Lueth, K.L., Why the Internet of Things is called Internet of Things: Definition, history, disambiguation, IoT Analytics.com, 2014, https://iot-analytics.com/internet-of-things-definition/#:~:text=A brief history of the Internet of Things&text=But the actual term “Internet, new exciting technology called RFID (accessed Aug. 23, 2020).

2. Gartner Glossary, Internet of Things, Gartner, https://www.gartner.com/en/information-technology/glossary/internet-of-things (accessed Aug. 27, 2020).

3. Regalado, A., Who Coined ‘Cloud Computing’?, MIT Technology Review, 2011, https://www.technologyreview.com/2011/10/31/257406/who-coined-cloud-computing/ (accessed Aug. 23, 2020).

4. Kaladhar, A. and Rao, K.S., Internet of things: a route to smart libraries. J. Adv. Lib. Sci., 4, 1, 29–34, 2018.

5. Litan, R., Vital signs via broadband: Remote health monitoring transmits savings, enhances lives, Better Healthcare Together, 2008, [Online]. Available: http://www.broadbandillinois.org/uploads/cms/documents/litan.pdf.

6. Atkinson, R.D. and Castro, D., Digital Quality of Life: Understanding the Personal and Social Benefits of the Information Technology Revolution, SSRN Electron. J, no. October, 2011, https://papers.ssrn.com/sol3/papers.cfm?abstract_id=1278185

7. Taylor, K., Sanghera, A., Steedman, M., Thaxter, M., Medtech and the internet of medical things: How connected medical devices are transforming healthcare, Deloitte, no. July, 2018, [Online]. Available: https://www2.deloitte.com/content/dam/Deloitte/global/Documents/Life-Sciences-Health-Care/gx-lshc-medtech-iomt-brochure.pdf.

8. Mayaan, D.G., The IoT Rundown For 2020: Stats, Risks, and Solutions, Security today, 2020, https://securitytoday.com/Articles/2020/01/13/The-IoT-Rundown-for-2020.aspx?Page=2 (accessed Aug. 28, 2020).

9. Piwek, L., Ellis, D.A., Andrews, S., Joinson, A., The Rise of Consumer Health Wearables: Promises and Barriers. PLoS Med., 13, 2, pp. 1–9, 2016.

10. Stanford Medicine, Apple Heart Study demonstrates ability of wearable technology to detect atrial fibrillation, Stanford Medicine News Centre, 2019, http://med.stanford.edu/news/all-news/2019/03/apple-heart-study-demon-strates-ability-of-wearable-technology.html (accessed Aug. 27, 2020).

11. Garge, G.K., Balakrishna, C., Datta, S.K., Consumer Healthcare: Current Trends in Consumer Health Monitoring. IEEE Consum. Electron. Mag., 7, 1, 38–46, 2018.

12. Peake, J.M., Kerr, G., Sullivan, J.P., A critical review of consumer wearables, mobile applications, and equipment for providing biofeedback, monitoring stress, and sleep in physically active populations. Front. Physiol., 9, JUN, 1–19, 2018.

13. Perez, M.V. et al., Large-Scale Assessment of a Smartwatch to Identify Atrial Fibrillation. N. Engl. J. Med., 381, 20, 1909–1917, Nov. 2019.

14. Garvin, E., What’s the Difference: A Look at Consumer and Medical-Grade Wearables in Healthcare, HIT Consultant, 2019, https://hitconsultant.net/2019/07/08/whats-the-difference-a-look-at-consumer-and-medical-grade-wearables-in-healthcare/#.X0UaU9MzbfY (accessed Aug. 25, 2020).

15. Frost & Sullivan, Wearables: Differentiating the Toys and Tools in Healthcare, Alliance of Advanced BioMedical Engineering, 2017, https://aabme.asme.org/posts/wearable-technologies-and-healthcare-differentiating-the-toys-and-tools-for-actionable-health-use-cases (accessed Aug. 25, 2020).

16. Cooper, L., Medical-grade devices vs. consumer wearables, electronic specifier, 2019, Electronic specifier, https://www.electronicspecifier.com/products/wearables/medical-grade-devices-vs-consumer-wearables (accessed Aug. 25, 2020).

17. Current health, Transition healthcare from the hospital to the home, Current health, 2020, https://currenthealth.com/ (accessed Aug. 27, 2020).

18. Abbott, Confirm Rx ICM ICapturing the Rhythm of Life, Abbott, 2019, https://confirmyourrhythm.com/.

19. Kim, T.H. et al., A temporary indwelling intravascular aphaeretic system for in vivo enrichment of circulating tumor cells. Nat. Commun., 10, 1, 1478, 2019.

20. Mitrani, R.D., Mcardle, A., Slane, M., Cogan, J., Myerburg, R.J., Wearable defibrillators in uninsured patients with newly diagnosed cardiomyopathy or recent revascularization in a community medical center. Am. Heart J., 165, 3, 386–392, 2013.

21. Epstein, A.E. et al., Wearable Cardioverter-Defibrillator Use in Patients Perceived to Be at High Risk Early Post-Myocardial Infarction. J. Am. Coll. Cardiol., 62, 21, 2000, LP – 2007, Nov. 2013.

22. Kao, A.C. et al., Wearable defibrillator use in heart failure (WIF): results of a prospective registry. BMC Cardiovasc. Disord., 12, 1, 123, 2012.

23. Seshadri, D.R. et al., Wearable sensors for monitoring the physiological and biochemical profile of the athlete. NPJ Digit. Med., 2, 1, 72, 2019.

24. Del Din, S. et al., Gait analysis with wearables predicts conversion to Parkinson disease. Ann. Neurol., 86, 3, 357–367, Sep. 2019.

25. U. F. and D. Administration, FDA approves pill with sensor that digitally tracks if patients have ingested their medication, FDA News Release, 2017, https://www.fda.gov/news-events/press-announcements/fda-approves-pill-sensor-digitally-tracks-if-patients-have-ingested-their-medication (accessed Aug. 24, 2020).

26. Plowman, R.S., Peters-Strickland, T., Savage, G.M., Digital medicines: clinical review on the safety of tablets with sensors. Expert Opin. Drug Saf., 17, 9, 849–852, 2018.

27. Muoio, D., Digital pill’ maker Proteus Digital Health files for bankruptcy, Mobi health news, 2020, https://www.mobihealthnews.com/news/digital-pill-maker-proteus-digital-health-files-bankruptcy (accessed Aug. 24, 2020).

28. Kent, C., Proteus Digital Health: A Sharp Lesson for Smart Pills?, Pharma Technology Focus, 2020, https://pharma.nridigital.com/pharma_apr20/proteus_digital_health_a_sharp_lesson_for_smart_pills.

29. Moorhead, P., Zavala, A., Kim, Y., Virdi, N.S., Efficacy and safety of a medication dose reminder feature in a digital health offering with the use of sensor-enabled medicines. J. Am. Pharm. Assoc., 57, 2, 155–161.e1, 2017.

30. Eunjung Cha, A., Smart pills’ with chips, cameras and robotic parts raise legal, ethical questions, The Washington Post, 2014, https://www.wash-ingtonpost.com/national/health-science/smart-pills-with-chips-cameras-and-robotic-parts-raise-legal-ethical-questions/2014/05/24/6f6d715e-dabb-11e3-b745-87d39690c5c0_story.html?utm_term=.643b662a8a7a (accessed Aug. 25, 2020).

31. Healthcare, S., AeroScout Hand Hygiene Compliance Monitoring, Stanley Healthcare, 2020, https://www.stanleyhealthcare.com/hospital-clinics/rtls/hand-hygiene-compliance-monitoring (accessed Aug. 27, 2020).

32. McCalla, S., Reilly, M., Thomas, R., McSpedon-Rai, D., An automated hand hygiene compliance system is associated with improved monitoring of hand hygiene. Am. J. Infect. Control, 45, 5, 492–497, 2017.

33. Strauch, J., Braun, T.M., Short, H., Use of an automated hand hygiene compliance system by emergency room nurses and technicians is associated with decreased employee absenteeism. Am. J. Infect. Control, 48, 5, 575–577, 2020.

34. Pinchin, J., Getting lost in hospitals costs the NHS and patients, The Guardian, 2017.

35. Brown, M., Shaw, D., Sharples, S., Le Jeune, I., Blakey, J., A survey-based cross-sectional study of doctors’ expectations and experiences of nontechnical skills for Out of Hours work. BMJ Open, 5, 2, e006102, Feb. 2015.

36. Ashton, K., Internet of Things case study: Boston Children’s Hospital and smarter healthcare, IoT News, 2017, https://iottechnews.com/news/2017/feb/28/internet-things-case-study-boston-childrens-hospital-and-smarter-healthcare/ (accessed Aug. 25, 2020).

37. Devlin, A.S., Wayfinding in healthcare facilities: contributions from environmental psychology. Behav. Sci. (Basel, Switzerland), 4, 4, 423–436, Oct. 2014.

38. Bridgera, Personal Emergency Response System (PERS) Bridgera Rescue-Personal Security Anywhere-You-Go, Bridgera, 2020.

39. Hyer, K. and Rudick, L., The Effectiveness of Personal Emergency Response Systems in Meeting the Safety Monitoring Needs of Home Care Clients. JONA J. Nurs. Adm., 24, 6, pp. 39–44, 1994, [Online]. Available: https://journals.lww.com/jonajournal/Fulltext/1994/06000/The_Effectiveness_of_Personal_Emergency_Response.10.aspx.

40. Mann, W.C., Belchior, P., Tomita, M.R., Kemp, B.J., Use of Personal Emergency Response Systems by Older Individuals With Disabilities. Assist. Technol., 17, 1, 82–88, Mar. 2005.

41. McKenna, A.C., Kloseck, M., Crilly, R., Polgar, J., Purchasing and Using Personal Emergency Response Systems (PERS): How decisions are made by community-dwelling seniors in Canada. BMC Geriatr., 15, 1, 1–9, 2015.

42. Heinbüchner, B., Hautzinger, M., Becker, C., Pfeiffer, K., Satisfaction and use of personal emergency response systems. Z. Gerontol. Geriatr., 43, 4, 219–223, 2010.

43. Hamill, M., Young, V., Boger, J., Mihailidis, A., Development of an automated speech recognition interface for personal emergency response systems. J. Neuroeng. Rehabil., 6, 1, 1–11, 2009.

44. Mackrill, J., Marshall, P., Payne, S.R., Dimitrokali, E., Cain, R., Using a bespoke situated digital kiosk to encourage user participation in healthcare environment design. Appl. Ergon., 59, 342–356, 2017.

45. Nicholas, D., Huntington, P., Williams, P., Three years of digital consumer health information: a longitudinal study of the touch screen health kiosk. Inf. Process. Manage., 39, 3, 479–502, 2003.

46. Nicholas, D., Huntington, P., Williams, P., Chahal, P., Determinants of Health Kiosk Use and Usefulness: Case Study of a Kiosk Which Serves a Multi-Cultural Population. Libri, 51, 2, 102–113, 2001.

47. Koch, S., Home telehealth—Current state and future trends. Int. J. Med. Inform., 75, 8, 565–576, 2006.

48. Finkelstein, S.M., Speedie, S.M., Potthoff, S., Home Telehealth Improves Clinical Outcomes at Lower Cost for Home Healthcare. Telemed. e-Health, 12, 2, 128–136, Apr. 2006.

49. Ashwood, J.S., Mehrotra, A., Cowling, D., Uscher-Pines, L., Direct-To-Consumer Telehealth May Increase Access To Care But Does Not Decrease Spending. Health Aff., 36, 3, 485–491, Mar. 2017.

50. Cady, R., Kelly, A., Finkelstein, S., Home telehealth for children with special healthcare needs. J. Telemed. Telecare, 14, 4, 173–177, Jun. 2008.

51. Angrish, S. et al., How effective is the virtual primary healthcare centers? An experience from rural India. J. Family Med. Prim. Care, 9, 2, 465–469, Feb. 2020.

52. Hennick, C., How Remote Patient Monitoring Programs Are Beneficial, HealthTech, 2020, https://healthtechmagazine.net/article/2020/04/how-remote-patient-monitoring-programs-are-beneficial (accessed Aug. 25, 2020).

53. Nakamura, N., Koga, T., Iseki, H., A meta-analysis of remote patient monitoring for chronic heart failure patients. J. Telemed. Telecare, 20, 1, 11–17, Dec. 2013.

54. Pollonini, L., Rajan, N.O., Xu, S., Madala, S., Dacso, C.C., A Novel Handheld Device for Use in Remote Patient Monitoring of Heart Failure Patients— Design and Preliminary Validation on Healthy Subjects. J. Med. Syst., 36, 2, 653–659, 2012.

55. Sanabria, M. et al., Remote Patient Monitoring Program in Automated Peritoneal Dialysis: Impact on Hospitalizations. Perit. Dial. Int., 39, 5, 472–478, Sep. 2019.

56. Pekmezaris, R. et al., The Impact of Remote Patient Monitoring (Telehealth) upon Medicare Beneficiaries with Heart Failure. Telemed. e-Health, 18, 2, 101–108, Jan. 2012.

57. Klersy, C. et al., Economic impact of remote patient monitoring: An integrated economic model derived from a meta-analysis of randomized controlled trials in heart failure. Eur. J. Heart Fail., 13, 4, 450–459, 2011.

58. Fleming, D.A., Edison, K.E., Pak, H., Telehealth Ethics. Telemed. e-Health, 15, 8, 797–803, Sep. 2009.

59. Ajaz, K., The Importance of Equipment Efficiency for the Healthcare Sector, Electronic Health Reporter, 2018, https://electronichealthreporter.com/the-importance-of-equipment-efficiency-for-the-healthcare-sector/ (accessed Aug. 25, 2020).

60. Matityaho, S., LogiTag System, The IoT Streamlines Healthcare Supply Chains, 2015, https://irp-cdn.multiscreensite.com/1fd06f20/files/uploaded/IoTInHealthcare_FINAL.pdf.

61. Man, L.C.K., Na, C.M., Kit, N.C., IoT-Based Asset Management System for Healthcare-Related Industries. Int. J. Eng. Bus. Manage., 7, 19, Jan. 2015.

62. Shiklo, B., RFID and IoT: A smart symbiosis for hospital asset tracking and management, ScienceSoft, 2018, https://www.scnsoft.com/blog/smart-hospital-asset-tracking.

63. BEHRTECH, 3 Great Benefits of IoT for Healthcare Asset Management, BehrTech Blog, 2020, https://behrtech.com/blog/iot-for-healthcare-asset-management/ (accessed Aug. 25, 2020).

64. Hanne, T., Melo, T., Nickel, S., Bringing Robustness to Patient Flow Management Through Optimized Patient Transports in Hospitals. INFORMS J. Appl. Anal., 39, 3, 241–255, Mar. 2009.

65. DAIC, FDA Grants Emergency Use Authorization to Vital Connect for Cardiac Monitoring in COVID-19 Patients, Diagnostic and Interventional Cardiology, 2020, https://www.dicardiology.com/content/fda-grants-emergency-use-authorization-vitalconnect-cardiac-monitoring-covid-19-patients (accessed Aug. 25, 2020).

66. Science Daily, Clinical-grade wearables offer continuous monitoring for COVID-19, ScienceDaily, 2020, https://www.sciencedaily.com/releases/2020/07/200701125410.htm (accessed Aug. 25, 2020).

67. Darwish, A. and Hassanien, A.E., Wearable and implantable wireless sensor network solutions for healthcare monitoring. Sensors, 11, 6, 5561–5595, 2011.

68. Zoll, Zoll Life Vest, Zoll Cardiac Diagnostics, 2020, https://lifevest.zoll.com/medical-professionals.

69. Spiegelman, J., Krenitsky, N., Syeda, S., Sutton, D., Moroz, L., Case Study Rapid Development and Implementation of a Covid-19 Telehealth Clinic for Obstetric Patients, NEJM Catal, no. May 15, 2020.

70. Aziz, A. et al., Telehealth for High-Risk Pregnancies in the Setting of the COVID-19 Pandemic. Am. J. Perinatol., 37, 8, 800–808, Jun. 2020.

1 *Corresponding author: uniqueruchi@rediffmail.com

Advanced Healthcare Systems

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