Future lines of research on phase angle: Strengths and limitations

• Published in: Reviews in endocrine & metabolic disorders Vol. 24; no. 3; pp. 563 - 583
• Main Authors: Bellido, Diego, García-García, Cristina, Talluri, Antonio, Lukaski, Henry C., García-Almeida, José Manuel
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.06.2023; Springer; Springer Nature B.V
• Subjects: Analysis; Ankle; Biomarkers; Biomedical research; Body composition; Body Composition - physiology; Clinical trials; COVID-19; Diabetes; Diagnosis; Disease; Electric Impedance; Endocrinology; Functional morphology; Health aspects; Heart diseases; Humans; Internal Medicine; Liver cancer; Liver diseases; Malnutrition; Mathematical models; Measurement techniques; Medical research; Medicine; Medicine & Public Health; Medicine, Experimental; Metabolic disorders; Metabolism; Nutritional Status; Obesity; Phenotypes; Renal failure; Sarcopenia; Standardization; Therapeutic applications; Wrist; Outcome research; Phase sensitive bioelectrical impedance analysis; Bioelectrical impedance vector analysis; Phase angle; Body composition; Morphofunctional assessment
• ISSN: 1389-9155; 1573-2606; 1573-2606
• DOI: 10.1007/s11154-023-09803-7

Bioelectrical impedance analysis (BIA) is the most widely used technique in body composition analysis. When we focus the use of phase sensitive BIA on its raw parameters Resistance (R), Reactance (Xc) and Phase Angle (PhA), we eliminate the bias of using predictive equations based on reference models. In particular PhA, have demonstrated their prognostic utility in multiple aspects of health and disease. In recent years, as a strong association between prognostic and diagnostic factors has been observed, scientific interest in the utility of PhA has increased. In the different fields of knowledge in biomedical research, there are different ways of assessing the impact of a scientific-technical aspect such as PhA. Single frequency with phase detection bioimpedance analysis (SF-BIA) using a 50 kHz single frequency device and tetrapolar wrist-ankle electrode placement is the most widely used bioimpedance approach for characterization of whole-body composition. However, the incorporation of vector representation of raw bioelectrical parameters and direct mathematical calculations without the need for regression equations for the analysis of body compartments has been one of the most important aspects for the development of research in this area. These results provide new evidence for the validity of phase-sensitive bioelectrical measurements as biomarkers of fluid and nutritional status. To enable the development of clinical research that provides consistent results, it is essential to establish appropriate standardization of PhA measurement techniques. Standardization of test protocols will facilitate the diagnosis and assessment of the risk associated with reduced PhA and the evaluation of changes in response to therapeutic interventions. In this paper, we describe and overview the value of PhA in biomedical research, technical and instrumental aspects of PhA research, analysis of Areas of clinical research (cancer patients, digestive and liver diseases, critical and surgical patients, Respiratory, infectious, and COVID-19, obesity and metabolic diseases, Heart and kidney failure, Malnutrition and sarcopenia), characterisation of the different research outcomes, Morphofunctional assessment in disease-related malnutrition and other metabolic disorders: validation of PhA with reference clinical practice techniques, strengths and limitations. Based on the detailed study of the measurement technique, some of the key issues to be considered in future PhA research. On the other hand, it is important to assess the clinical conditions and the phenotype of the patients, as well as to establish a disease-specific clinical profile. The appropriate selection of the most critical outcomes is another fundamental aspect of research.