Abstract
Rapid growth of sensor and computing platforms have introduced the wearable systems. In recent years, wearable systems have led to new applications across all medical fields. The aim of this review is to present current state-of-the-art approach in the field of wearable system based cancer detection and identify key challenges that resist it from clinical adoption. A total of 472 records were screened and 11 were finally included in this study. Two types of records were studied in this context that includes 45% research articles and 55% manufactured products. The review was performed per PRISMA guidelines where considerations was given to records that were published or reported between 2009 and 2017. The identified records included 4 cancer detecting wearable systems such as breast cancer (36.3%), skin cancer (36.3%), prostate cancer (18.1%), and multi-type cancer (9%). Most works involved sensor based smart systems comprising of microcontroller, Bluetooth module, and smart phone. Few demonstrated Ultra-Wide Band (i.e. UWB) antenna based wearable systems. Skin cancer detecting wearable systems were most comprehensible ones. The current works are gradually progressing with seamless integration of sensory units along with smart networking. However, they lack in cloud computing and long-range communication paradigms. Artificial intelligence and machine learning are key ports that need to be attached with current wearable systems. Further, clinical inertia, lack of awareness, and high cost are altogether pulling back the actual growth of such system. It is well comprehended that upon sincere orientation of all identified challenges, wearable systems would emerge as vital alternative to futuristic cancer detection.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baig, M.M., GholamHosseini, H., Moqeem, A.A., Mirza, F., Lindén, M., and Systematic Review, A., of Wearable Patient Monitoring Systems – Current Challenges and Opportunities for Clinical Adoption. J. Med. Syst. 41(115), 2017.
Eaton, S., Roberts, S., and Turner, B., Delivering person centred care in long term conditions. BMJ. 350:h181, 2015.
Cancer facts & figures 2017, Available at https://www.cancer.org/research/cancer-facts-statistics/all-cancer-facts-figures/cancer-facts-figures-2017.html, Accessed on July 15, 2017.
O’Shaughnessy, C., The Basics: National Spending for Long-Term Services and Supports. Vol. 2012. National Health Policy Forum. George Washington University, Washington, DC, 2013.
Sidhu, M.S., et al., Long-term conditions, self-management and systems of support: An exploration of health beliefs and practices within the Sikh community, Birmingham, UK. Ethn. Health:1–17, 2016.
Ray, P.P., Understanding the Role of Internet of Things Towards Providing Smart e-Healthcare Services. Bio Med Res. Allied Acad. 28(4):1604–1609, 2017.
Wearable Technology Market worth 51.60 Billion USD by 2022, Available at www.marketsandmarkets.com › Press Releases, Accessed on July 10, 2017.
Ray, P. P., A Survey on Internet of Things Architectures. J. King Saud Univ. Comput. Inf. Sci. 2016. Elsevier. doi: https://doi.org/10.1016/j.jksuci.2016.10.003.
Ray, P. P., A Survey of IoT Cloud Platforms. Futur. Comput. Inf. J. 1(1–2):35–46, 2016. Elsevier.
Sabesan, S., and Sankar, R., Improving long-term management of epilepsy using a wearable multimodal seizure detection system. Epilepsy Behav. 46:56–57, 2015.
VitalPatch, Available at https://vitalconnect.com/solutions/vitalpatch/, Accessed on July 12, 2017.
Ray, P.P., An IR Sensor Based Smart System to Approximate Core Body Temperature. J. Med. Syst. 41(123), 2017. https://doi.org/10.1007/s10916-017-0770-z.
Goyal, K., and Agarwal, R., Pulse based sensor design for wrist pulse signal analysis and health diagnosis. Biomed. Res. 28(12):5187–5195, 2017.
RunScribe, Available at http://runscribe.com/, Accessed on July 14, 2017.
Pandian, P., et al., Smart vest: Wearable multi-parameter remote physiological monitoring system. Med. Eng. Phys. 30(4):466–477, 2008.
Sardini, E., Serpelloni, M., and Pasqui, V., Wireless wearable Tshirt for posture monitoring during rehabilitation exercises. IEEE Trans. Instrum. Meas. 64(2):439–448, 2015.
Soh, P.J., et al., Wearable wireless health monitoring: Current developments, challenges, and future trends. IEEE Microw. Mag. 16(4):55–70, 2015.
Xu, J., et al., Personalized active learning for activity classification using wireless wearable sensors. IEEE J. Sel. Top. Sign. Proces. 10(5):865–876, 2016.
Pantelopoulos, A., and Bourbakis, N., Design of the new prognosis wearable system-prototype for health monitoring of people at risk. In: Advances in Biomedical Sensing, Measurements, Instrumentation and Systems, Springer, pp. 29–42, 2010.
Moher, D., Liberati, A., Tetzlaff, J., and Altman, D.G., Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. Int. J. Surg. 8:336–341, 2010.
Attili, S.K., Lesar, A., McNeill, A., Camacho-Lopez, M., Moseley, H., Ibbotson, S., Samuel, I.D.W., and Ferguson, J., An open pilot study of ambulatory photodynamic therapy using a wearable low-irradiance organic light-emitting diode light source in the treatment of nonmelanoma skin cancer. Br. J. Dermatol. 161:170–173, 2009.
Bahrami, H., Porter, E., Santorelli, A., Gosselin, B., Popović, M., and Rusch, L.A., Flexible Sixteen Antenna Array for Microwave Breast Cancer Detection. IEEE Trans. Biomed. Eng. 62(10):2516–2525, 2015.
Rahman, A., Islam, M.T., Singh, M.J., Kibriam, S., and Akhtaruzzaman, M., Electromagnetic Performances Analysis of an Ultra-wideband and Flexible Material Antenna in Microwave Breast Imaging: To Implement A Wearable Medical Bra. Sci. Rep. 6:38906, 2016.
Teng, F., Cormier, T., Budge, A. S., Chaudhury, R., Pera, V., Istfan, R., Chargin, D., Brookfield, S., Ko, N. U., and Roblyer, D. M., Wearable near-infrared optical probe for continuous monitoring during breast cancer neoadjuvant chemotherapy infusions. J. Biomed. Opt. 22(1):014001–1–014001-8, 2017.
Godoy, D.D., Jia, J., and Jiang, X., Demo Abstract: RIO-40C - A Low-Cost Wearable Sunlight Exposure Monitor for Skincare. In: 2nd ACM/IEEE International Conference on Internet-of-Tings Design and Implementation (IoTDI), 2017.
My UV Patch, Available at http://www.laroche-posay.us/my-uv-patch, Accessed on July 3, 2017.
Ultra Violet, Available at http://www.liveultrahealthy.com/, Accessed on July 11, 2017.
ScanMed, Available at http://www.scanmed.com/products/prostate-pelvic-coil/, Accessed on July 7, 2017.
VylyV, Available at http://www.vylvy.net/, Accessed on July 14, 2017.
iTBra, Available at http://cyrcadiahealth.com, Accessed on July 15, 2017.
M. MacRae “Wearable Cancer Monitors: Accessories to a Cure”, Available at https://aabme.asme.org/posts/wearable-cancer-monitors-accessories-to-a-cure, Accessed on July 17, 2017.
Francioso, L., Pascali, C.D., Bartali, R., Morganti, E., Lorenzelli, L., Siciliano, P., and Laidani, N., PDMS/Kapton Interface Plasma Treatment Effects on the Polymeric Package for a Wearable Thermoelectric Generator. ACS Appl. Mater. Interfaces. 5(14):6586–6590, 2013.
Foster, K.R., Koprowski, R., and Skufca, J.D., Machine learning, medical diagnosis, and biomedical engineering research – commentary. BioMed. Eng. OnLine. 13:94, 2014.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of Interest
Authors declare no conflict of interest.
Ethical Approval
This article does not contain any studies with human participants performed by any of the authors.
Additional information
This article is part of the Topical Collection on Mobile & Wireless Health
Rights and permissions
About this article
Cite this article
Ray, P.P., Dash, D. & De, D. A Systematic Review of Wearable Systems for Cancer Detection: Current State and Challenges. J Med Syst 41, 180 (2017). https://doi.org/10.1007/s10916-017-0828-y
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s10916-017-0828-y