Abstract
A simple experimental protocol applying a quantitative ultrasound (QUS) pulse-echo technique was used to measure the acoustic parameters of healthy femoral diaphyses of Wistar rats in vivo. Five quantitative parameters [apparent integrated backscatter (AIB), frequency slope of apparent backscatter (FSAB), time slope of apparent backscatter (TSAB), integrated reflection coefficient (IRC), and frequency slope of integrated reflection (FSIR)] were calculated using the echoes from cortical and trabecular bone in the femurs of 14 Wistar rats. Signal acquisition was performed three times in each rat, with the ultrasound signal acquired along the femur's central region from three positions 1 mm apart from each other. The parameters estimated for the three positions were averaged to represent the femur diaphysis. The results showed that AIB, FSAB, TSAB, and IRC values were statistically similar, but the FSIR values from Experiments 1 and 3 were different. Furthermore, Pearson's correlation coefficient showed, in general, strong correlations among the parameters. The proposed protocol and calculated parameters demonstrated the potential to characterize the femur diaphysis of rats in vivo. The results are relevant because rats have a bone structure very similar to humans, and thus are an important step toward preclinical trials and subsequent application of QUS in humans.
Highlights
Bone is formed by specialized connective tissue; its extracellular matrix is calcified but maintains a degree of elasticity [1,2]
The results showed that apparent integrated backscatter (AIB), frequency slope of apparent backscatter (FSAB), time slope of apparent backscatter (TSAB), and integrated reflection coefficient (IRC) values were statistically similar, but the frequency slope of integrated reflection (FSIR) values from Experiments 1 and 3 were different
The present study aimed to develop a quantitative ultrasound (QUS) method using a pulse-echo technique to extract five parameters: apparent integrated backscatter (AIB), frequency slope of apparent backscatter (FSAB), time slope of apparent backscatter (TSAB), integrated reflection coefficient (IRC), and frequency slope of integrated reflection (FSIR) by processing ultrasonic backscattered and reflection echoes to characterize cortical and trabecular bone from healthy bone diaphyses of Wistar rats in vivo
Summary
Bone is formed by specialized connective tissue; its extracellular matrix is calcified but maintains a degree of elasticity [1,2]. The process of fracture healing is complex [3,4], involving cellular proliferation and differentiation, chemotaxis, and synthesis of extracellular matrix [3], with several stages of repair with a well-defined temporal and spatial sequence [5,6]. Protopappas et al [11], using computational simulations and experiments [4], found that material properties and geometrical features change, influencing the propagation of ultrasound waves along the cortex of long bones. Hakulinen et al [13] studied the measurement of bone density and mechanical properties by ultrasonic propagation parameters, reporting results that indicated a potential for diagnosing osteoporosis
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