Design and Development of a Low-Cost Arduino-Based Electrical BioImpedance Spectrometer

Khusnul Ain, R. Arif Wibowo, Soegianto Soelistiono, Lailatul Muniroh, Bayu Ariwanto

DOI: 10.4103/jmss.JMSS_67_18

Abstract


Background: Bioimpedance spectroscopy (BIS) is a device used to measure electrical impedance at frequencies from 0 Hz to 1 MHz. Many clinical diagnosis and fundamental researches, especially in the field of physiology and pathology, rely on this device. The device can be used to estimate human body composition, through the information of total body water, extracellular fluid and intracellular fluid, fat-free mass, and fat mass from its impedance. BIS analysis can provide physiological statuses such as ischemia, pulmonary edema, skin cancer, and intramuscular tumors. BIS is expected to be used even more widely, both for hospital or home-based use, particularly because BIS handy, compact, inexpensive, and less power-consuming with adequately accurate real-time. In previous research, the BIS design was based on the magnitude-ratio and phase difference detection using the AD8302 gain-phase detector method which resulted in an operating range between 20 kHz and 1 MHz. However, the impedance was obtained from the logarithmic ratio magnitude which caused the device to have limited accuracy at frequencies <20 kHz. Methods: In this research, we conduct design and development of a low-cost arduino-based electrical bioimpedance spectrometer. Results: The low-cost bioimpedance spectrometry was successfully developed using AD9850 as the programmable function generator, OPA2134 as the OpAm of voltage-controlled current source, AD620A as the instrument amplifier and AD536A as the alternating current to direct current converter which could work accurately from 0 Hz to 100 kHz. Conclusion: The multi-frequency bioimpedance device developed in this research has the capability to safely measure the impedance of the human body due to its relatively stable electric current, which is equal to (0.370 ± 0.003) mA with frequencies ranging from 5 to 200 kHz and has an accuracy of over 90% in the frequency range of 10 Hz to 100 kHz.


Keywords


Arduino based, electrical bioimpedance, low-cost, spectrometer

Full Text:

PDF

References


Gómez-Ambrosi J, González-Crespo I, Catalán V, Rodríguez A, Moncada R, Valentí V, et al. Clinical usefulness of abdominal bioimpedance (ViScan) in the determination of visceral fat and its application in the diagnosis and management of obesity and its comorbidities. Clin Nutr 2018;37:580-9.

Costa RF, Cyrino ES. Vertical segmental tetrapolar bioimpedance for excess body fat assessment in adolescents. J Pediatr (Rio J) 2016;92:319-20.

Abbas SR, Thijssen S, Penne EL, Raimann JG, Liu L, Sipahioglu MH, et al. Effect of change in fluid status evaluated by bioimpedance techniques on body composition in hemodialysis patients. J Ren Nutr 2018;28:183-90.

Qin ES, Bowen MJ, Chen WF. Diagnostic accuracy of bioimpedance spectroscopy in patients with lymphedema: A retrospective cohort analysis. J Plast Reconstr Aesthet Surg 2018;71:1041-50.

Mayer M, Brunner P, Merwa R, Scharfetter H. Monitoring of lung edema using focused impedance spectroscopy: A feasibility study. Physiol Meas 2005;26:185-92.

Prado-Olivarez J, Arellano-Olivares F, Padilla-Medina J, Diaz-Carmona A, Ramirez-Agundis A, Espinosa-Calderon M, et al. Bioimpedance phase angle analysis of foot skin in diabetic patients: An experimental case study. IRBM 2015;36:233-9.

Sun TP, Ching CT, Cheng CS, Huang SH, Chen YJ, Hsiao CS, et al. The use of bioimpedance in the detection/screening of tongue cancer. Cancer Epidemiol 2010;34:207-11.

Kun S, Ristic B, Peura RA, Dunn RM. Algorithm for tissue ischemia estimation based on electrical impedance spectroscopy. IEEE Trans Biomed Eng 2003;50:1352-9.

Aberg P, Nicander I, Hansson J, Geladi P, Holmgren U, Ollmar S. Skin cancer identification using multifrequency electrical impedance-a potential screening tool. IEEE Trans Biomed Eng 2004;51:2097-102.

Skourou C, Hoopes PJ, Strawbridge RR, Paulsen KD. Feasibility studies of electrical impedance spectroscopy for early tumor detection in rats. Physiol Meas 2004;25:335-46.

Yang Y, Wang J, Yu G, Niu F, He P. Design and preliminary evaluation of a portable device for the measurement of bioimpedance spectroscopy. Physiol Meas 2006;27:1293-310.

Mohamadou Y, Momo F, Theophile L, Njike Kouekeu Landry C, Fabrice T, Emmanuel S. Accuracy enhancement in low frequency gain and phase detector (AD8302) based bio-impedance spectroscopy system. Measurement 2018;123:304-8.

Mylott E, Kutschera E, Widenhorn R. Bioelectrical impedance analysis as a laboratory activity: At the interface of physics and the body. Am J Phys 2014;82:521-8.

Kamat D. K, Bagul D, and Patil P. M. Blood glucose measurement using bioimpedance technique. Advances in Electronics 2014;2014:4-9.


Refbacks

  • There are currently no refbacks.


 

  https://e-rasaneh.ir/Certificate/22728

https://e-rasaneh.ir/

ISSN : 2228-7477