Measurement of mean subcutaneous fat thickness: eight . . . Ultrasound (US) provides the most accurate technique for thickness measurements of subcutaneous adipose tissue (SAT) layers This US method was recently standardised using eight sites to capture SAT patterning and allows distinguishing between fat and embedded fibrous structures
High-frequency ultrasound as a scientific tool for skin . . . Our findings showed that HFUS imaging is a reproducible and powerful tool for the diagnosis, clinical management and therapy monitoring of skin conditions It is also a helpful tool for assessing the performance of dermatological products
Ultrasonographic analysis of facial skin thickness in . . . Ultrasound images clearly distinguished the layers (epidermis, dermis, subcutaneous tissue + muscle layer) Distances were measured by drawing straight lines perpendicular from the skin surface to the subcutaneous tissue using Sante DICOMDIR Viewer software Approximate schematic diagram (left), actual measurement screen (big screen) FIGURE 2
Measurement of subcutaneous adipose tissue thickness by near . . . Obesity is strongly associated with the risks of diabetes and cardiovascular disease, and there is a need to measure the subcutaneous adipose tissue (SAT) layer thickness and to understand the distribution of body fat
Ultrasound-guided measurement of skin and subcutaneous tissue . . . To measure skin thickness (ST) and skin + subcutaneous layer thickness (SCT) by ultrasound and estimate the risk of intramuscular injection (IM) with different needle lengths across injection sites according to age group