A Design of Rheoencephalography Acquisition System Based on Bioimpedance Measurement as the Basis for Assessment of Cerebral Circulation
Main Article Content
Abstract
To evaluate human’s cerebral blood flow (CBF), electrical rheoencephalography (REG) is one of the most notable electrophysiological technique, which has been investigated for a long period. This technique non-invasively measures the electrical impedance of the cranial cavity region through scalp electrodes reflecting the changes in brain’s conductivity due to blood circulation during cardiac cycles. This paper aims to present a design of low-cost system able to continuously record rheoencephalography signal using bioimpedance method. This REG system comprises of main components such as: voltage-controlled current source (VCCS), signal recorder, AM demodulator, analog-to-digital converter, digital signal processor, and signal displayer. This design has a prominent feature that allows to measure the signal without requiring of high resolution ADC (usually 24 bit) and utilizes the simple envelop detecting circuit for AM demodulator. The high-frequency VCCS in the design is also thoroughly designed to ensure the quality of recording signal. The design is implemented, and then is evaluated on simple RC series model for static impedance and standard bio-impedance simulation device (with two kind of waveforms) for dynamic impedance. The results show the high correlation between the standard and recorded signals: R2 is 0.9815 for RC series model; RMSE and rRMSE for waveform 1 are 17.14 and 0.0857%; RMSE and rRMSE for waveform 2 are 13.58 and 0.0679% correspondingly.
Keywords
Rheoencephalography (REG), Cerebral Blood Flow (CBF), AM demodulator, Analog-to-digital converter (ADC), Howland Current Pump
Article Details
References
[1] C. Guyton, John E. Hall (2006). Textbook of Medical of Physiology. International Edition ISBN 0-8089-2317-X, chap. 61, pp. 761.
[2] Donald A. S. (1997). Head Injury. Chapman & Hall Medical, chap. Clinical Examination and Grading, pp.145–165.
[3] Polzer K., Schuhfried F. (1950). Rheographische untersuchungen am schedel. Z Nervenheilkd, vol. 3, pp. 295–298.
[4] Lifshitz K. (1970). Electrical impedance cephalography (rhoencephalography). Biomedical Engineering Systems, pp. 21–64.
[5] Seipel J. H. (1967). The Biophysical Basis and Clinical Applications of Rheoencephalography. Federal Aviation Administration, office of Aviation Medicine, Georgetown Clinical Research Institute, Washington.
[6] Yarullin KH. KH. (1967). Clinical Rheoencephalography. Medizina, Leningrad.
[7] Lechner H., Martin F. (1969). Introduction to rheoencephalographic methods. In: Lechner H., Geyer N., Lugaresi E., Martin F., Lifshitz K. , Markovich S. (Eds.), Rhoence-phalography and Plethysmographical Methods, Excerpta Med. Foundation, Amsterdam, pp. 3–9.
[8] Namon R., Markovich S. E. (1967). Monopolar rheoencephalography. Electroencephalog. Clin. Neurophysiol., vol. 22, pp. 272-274.
[9] Lifshitz K. (1967). An investigation of electrode guarding and frequency effects in rheoencephalography. Rheoencephalography and Plethysmographical Methods, pp. 10–16.
[10] Namon R., Markovich S. E. (1967). Monopolar rheoencephalography. Electroencephalography and Clinical Neurophysiology, vol.22, pp. 272–274.
[11] Perez J. J., Guijarro E., Barcia J. A. (2000). Quantification of intracranial contribution to rheoencephalography by a numerical model of the head. Clinical Neurophysiology, vol. 111, pp. 1306–1314.
[12] Yao D. (2003). High-resolution EEG mapping: an equivalent charge-layer approach. Physics in Medicine and Biology, vol. 48, pp. 1997–2011.
[13] Ferree T. C., Eriksen K. J., Tucker D. M. (2000). Regional head tissue conductivity estimation for improved EEG analysis. IEEE Trans. Biomed. Eng, vol. 47, pp. 1584–92
[14] Konstantin S. B., Jacov S. P., Oleg S. U. (2014). Modelling the Ability of Rheoencephalography to Measure Cerebral Blood Flow. Journal of Electrical Bioimpedance, vol. 5, pp. 110–113.
[15] Carlos P., John S. M. (1964). A critical evaluation of rheoencephalography in control subjects and in proven cases of cerebrovascular disease. J. Neurol. Neurosurg. Psychiat., vol. 27, pp. 66–72.
[16] http://www.analog.com/media/en/technical-documentation/data-sheets/AD8421.pdf.
[17] https://medis.company/cms/uploads/PDF/VasoScreen_Product_Line_Screen.pdf.
[18] http://www.ti.com/lit/ds/symlink/sbos115.pdf.
[19] http://www.ti.com/lit/ds/symlink/ads1120.pdf.
[20] http://www.ti.com/lit/ds/symlink/iso7421.pdf
[21] Elliot M. (2014). Bioelectrical Impedance Analysis as a Laboratory Activity: At the Interface of Physics and the Body. American Journal of Physics, pp. 521-528.
[2] Donald A. S. (1997). Head Injury. Chapman & Hall Medical, chap. Clinical Examination and Grading, pp.145–165.
[3] Polzer K., Schuhfried F. (1950). Rheographische untersuchungen am schedel. Z Nervenheilkd, vol. 3, pp. 295–298.
[4] Lifshitz K. (1970). Electrical impedance cephalography (rhoencephalography). Biomedical Engineering Systems, pp. 21–64.
[5] Seipel J. H. (1967). The Biophysical Basis and Clinical Applications of Rheoencephalography. Federal Aviation Administration, office of Aviation Medicine, Georgetown Clinical Research Institute, Washington.
[6] Yarullin KH. KH. (1967). Clinical Rheoencephalography. Medizina, Leningrad.
[7] Lechner H., Martin F. (1969). Introduction to rheoencephalographic methods. In: Lechner H., Geyer N., Lugaresi E., Martin F., Lifshitz K. , Markovich S. (Eds.), Rhoence-phalography and Plethysmographical Methods, Excerpta Med. Foundation, Amsterdam, pp. 3–9.
[8] Namon R., Markovich S. E. (1967). Monopolar rheoencephalography. Electroencephalog. Clin. Neurophysiol., vol. 22, pp. 272-274.
[9] Lifshitz K. (1967). An investigation of electrode guarding and frequency effects in rheoencephalography. Rheoencephalography and Plethysmographical Methods, pp. 10–16.
[10] Namon R., Markovich S. E. (1967). Monopolar rheoencephalography. Electroencephalography and Clinical Neurophysiology, vol.22, pp. 272–274.
[11] Perez J. J., Guijarro E., Barcia J. A. (2000). Quantification of intracranial contribution to rheoencephalography by a numerical model of the head. Clinical Neurophysiology, vol. 111, pp. 1306–1314.
[12] Yao D. (2003). High-resolution EEG mapping: an equivalent charge-layer approach. Physics in Medicine and Biology, vol. 48, pp. 1997–2011.
[13] Ferree T. C., Eriksen K. J., Tucker D. M. (2000). Regional head tissue conductivity estimation for improved EEG analysis. IEEE Trans. Biomed. Eng, vol. 47, pp. 1584–92
[14] Konstantin S. B., Jacov S. P., Oleg S. U. (2014). Modelling the Ability of Rheoencephalography to Measure Cerebral Blood Flow. Journal of Electrical Bioimpedance, vol. 5, pp. 110–113.
[15] Carlos P., John S. M. (1964). A critical evaluation of rheoencephalography in control subjects and in proven cases of cerebrovascular disease. J. Neurol. Neurosurg. Psychiat., vol. 27, pp. 66–72.
[16] http://www.analog.com/media/en/technical-documentation/data-sheets/AD8421.pdf.
[17] https://medis.company/cms/uploads/PDF/VasoScreen_Product_Line_Screen.pdf.
[18] http://www.ti.com/lit/ds/symlink/sbos115.pdf.
[19] http://www.ti.com/lit/ds/symlink/ads1120.pdf.
[20] http://www.ti.com/lit/ds/symlink/iso7421.pdf
[21] Elliot M. (2014). Bioelectrical Impedance Analysis as a Laboratory Activity: At the Interface of Physics and the Body. American Journal of Physics, pp. 521-528.