Using the 9th–11th rib section to predict carcase tissue composition in Blackbelly sheep

An electronic circuit for contactless detection of impedance changes in a tissue is presented. It operates on the principle of resonant frequency change of the resonator having the observed tissue as a dielectric. The operating frequency reflects the tissue dielectric properties (i.e., the tissue composition and on the tissue physiological changes). The sensor operation was tested within a medical application by measuring the breathing of a patient, which was an easy detectable physiological process. The advantage over conventional contact bioimpedance measurement methods is that no direct contact between the resonator and the body is required. Furthermore, the sensor’s wide operating range, ability to adapt to a broad range of measured materials, fast response, low power consumption, and small outline dimensions enables applications not only in the medical sector, but also in other domains. This can be extended, for example, to food industry or production maintenance, where the observed phenomena are reflected in dynamic dielectric properties of the observed object or material.

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Effect of starvation on the tissue composition of the small intestine in the rat

American Journal of Physiology-Legacy Content ◽

10.1152/ajplegacy.1968.215.1.75 ◽

1968 ◽

Vol 215 (1) ◽

pp. 75-77 ◽

Cited By ~ 109

Author(s):

M Steiner ◽

HR Bourges ◽

LS Freedman ◽

SJ Gray

Keyword(s):

Small Intestine ◽

Tissue Composition

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Dissociation of saline-induced natriuresis from urea washout in the rat

AJP Renal Physiology ◽

10.1152/ajprenal.1981.241.3.f250 ◽

1981 ◽

Vol 241 (3) ◽

pp. F250-F256

Author(s):

F. J. Gennari ◽

C. Johns ◽

C. R. Caflisch ◽

S. Cortell

Keyword(s):

Renal Artery ◽

Water Content ◽

Renal Tissue ◽

Tissue Composition ◽

Outer Medulla ◽

Experimental Conditions ◽

Artery Pressure ◽

Urea Content ◽

Saline Loading ◽

Solute Composition

Medullary urea washout has been postulated to play a major role in the natriuretic response to volume expansion (VE). To examine this hypothesis, renal tissue solute composition was measured in a natriuretic and nonnatriuretic model of VE. Renal tissue composition was analyzed during hydropenia, acute VE, acute VE with renal artery pressure reduced to 70 mmHg at the onset of saline loading (immediate clamping), and acute VE with renal artery pressure reduced to 70 mmHg after 45 min of saline loading (delayed clamping). Immediate clamping, a nonnatriuretic model of VE, prevented VE-induced urea washout and the increase in sodium and water content in the cortex and outer medulla. Delayed clamping, a natriuretic model of VE, produced a pattern of tissue composition very similar to immediate clamping. Tissue urea content was not significantly different in the two protocols and only minor differences in sodium and water content were noted. Thus, under these experimental conditions, VE-induced natriuresis can be dissociated from medullary urea washout, and other mechanisms must be invoked to explain the increased sodium excretion.

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Predicting composition of leg sections with anthropometry and bioelectrical impedance analysis, using magnetic resonance imaging as reference

Clinical Science ◽

10.1042/cs0960647 ◽

1999 ◽

Vol 96 (6) ◽

pp. 647-657 ◽

Cited By ~ 38

Author(s):

N. J. FULLER ◽

C. R. HARDINGHAM ◽

M. GRAVES ◽

N. SCREATON ◽

A. K. DIXON ◽

...

Keyword(s):

Magnetic Resonance Imaging ◽

Adipose Tissue ◽

Magnetic Resonance ◽

Coefficient Of Variation ◽

Lower Limb ◽

Bioelectrical Impedance Analysis ◽

Bioelectrical Impedance ◽

Impedance Analysis ◽

Tissue Composition ◽

Resonance Imaging

Magnetic resonance imaging (MRI) was used to evaluate and compare with anthropometry a fundamental bioelectrical impedance analysis (BIA) method for predicting muscle and adipose tissue composition in the lower limb. Healthy volunteers (eight men and eight women), aged 41 to 62 years, with mean (S.D.) body mass indices of 28.6 (5.4) kg/m2 and 25.1 (5.4) kg/m2 respectively, were subjected to MRI leg scans, from which 20-cm sections of thigh and 10-cm sections of lower leg (calf) were analysed for muscle and adipose tissue content, using specifically developed software. Muscle and adipose tissue were also predicted from anthropometric measurements of circumferences and skinfold thicknesses, and by use of fundamental BIA equations involving section impedance at 50 kHz and tissue-specific resistivities. Anthropometric assessments of circumferences, cross-sectional areas and volumes for total constituent tissues matched closely MRI estimates. Muscle volume was substantially overestimated (bias: thigh, -40%; calf, -18%) and adipose tissue underestimated (bias: thigh, 43%; calf, 8%) by anthropometry, in contrast to generally better predictions by the fundamental BIA approach for muscle (bias: thigh, -12%; calf, 5%) and adipose tissue (bias: thigh, 17%; calf, -28%). However, both methods demonstrated considerable individual variability (95% limits of agreement 20–77%). In general, there was similar reproducibility for anthropometric and fundamental BIA methods in the thigh (inter-observer residual coefficient of variation for muscle 3.5% versus 3.8%), but the latter was better in the calf (inter-observer residual coefficient of variation for muscle 8.2% versus 4.5%). This study suggests that the fundamental BIA method has advantages over anthropometry for measuring lower limb tissue composition in healthy individuals.

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