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1.
[Dialysis monitoring: peritoneal equilibrium test, regional citrate anticoagulation and residual renal function].
Bargnoux, AS, Barguil, Y, Zaoui, E, Jean, G, Cristol, JP
Annales de biologie clinique. 2019;(4):391-396
Abstract
The SFBC working group aimed to deal with biological tests outside the French nomenclature that may be useful for the follow-up of dialysis patients. Our discussion was divided into 3 parts: 1) evaluation of peritoneal membrane characteristics; 2) monitoring of renal replacement therapy using regional citrate anticoagulation; 3) estimation of residual renal function (RRF). International recommendations underline the importance of assessing peritoneal membrane characteristics for peritoneal dialysis prescription. This peritoneal equilibrium test requires the measurement in dialysate of the following parameters: glucose, urea, creatinine and sodium. As part of the monitoring of continuous renal replacement therapy using regional citrate anticoagulation, the determination of ionized calcium assay is essential according to national and international guidelines to ensure a balance between effective anticoagulation and appropriate calcium levels. Finally, the RRF plays a key role in the dialysis adequacy and patient survival. European and international recommendations highlight the potential interest of RRF in peritoneal dialysis and hemodialysis. The RRF corresponds to the mean of urinary urea and creatinine clearance, assessed from a urine collection with measurement of urinary urea.
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Magnetic resonance thermometry and its biological applications - Physical principles and practical considerations.
Odéen, H, Parker, DL
Progress in nuclear magnetic resonance spectroscopy. 2019;:34-61
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Abstract
Most parameters that influence the magnetic resonance imaging (MRI) signal experience a temperature dependence. The fact that MRI can be used for non-invasive measurements of temperature and temperature change deep inside the human body has been known for over 30 years. Today, MR temperature imaging is widely used to monitor and evaluate thermal therapies such as radio frequency, microwave, laser, and focused ultrasound therapy. In this paper we cover the physical principles underlying the biological applications of MR temperature imaging and discuss practical considerations and remaining challenges. For biological tissue, the MR signal of interest comes mostly from hydrogen protons of water molecules but also from protons in, e.g., adipose tissue and various metabolites. Most of the discussed methods, such as those using the proton resonance frequency (PRF) shift, T1, T2, and diffusion only measure temperature change, but measurements of absolute temperatures are also possible using spectroscopic imaging methods (taking advantage of various metabolite signals as internal references) or various types of contrast agents. Currently, the PRF method is the most used clinically due to good sensitivity, excellent linearity with temperature, and because it is largely independent of tissue type. Because the PRF method does not work in adipose tissues, T1- and T2-based methods have recently gained interest for monitoring temperature change in areas with high fat content such as the breast and abdomen. Absolute temperature measurement methods using spectroscopic imaging and contrast agents often offer too low spatial and temporal resolution for accurate monitoring of ablative thermal procedures, but have shown great promise in monitoring the slower and usually less spatially localized temperature change observed during hyperthermia procedures. Much of the current research effort for ablative procedures is aimed at providing faster measurements, larger field-of-view coverage, simultaneous monitoring in aqueous and adipose tissues, and more motion-insensitive acquisitions for better precision measurements in organs such as the heart, liver, and kidneys. For hyperthermia applications, larger coverage, motion insensitivity, and simultaneous aqueous and adipose monitoring are also important, but great effort is also aimed at solving the problem of long-term field drift which gets interpreted as temperature change when using the PRF method.
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Blood Biomarker Profiling and Monitoring for High-Performance Physiology and Nutrition: Current Perspectives, Limitations and Recommendations.
Pedlar, CR, Newell, J, Lewis, NA
Sports medicine (Auckland, N.Z.). 2019;(Suppl 2):185-198
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Abstract
Blood test data were traditionally confined to the clinic for diagnostic purposes, but are now becoming more routinely used in many professional and elite high-performance settings as a physiological profiling and monitoring tool. A wealth of information based on robust research evidence can be gleaned from blood tests, including: the identification of iron, vitamin or energy deficiency; the identification of oxidative stress and inflammation; and the status of red blood cell populations. Serial blood test data can be used to monitor athletes and make inferences about the efficacy of training interventions, nutritional strategies or indeed the capacity to tolerate training load. Via a profiling and monitoring approach, blood biomarker measurement combined with contextual data has the potential to help athletes avoid injury and illness via adjustments to diet, training load and recovery strategies. Since wide inter-individual variability exists in many biomarkers, clinical population-based reference data can be of limited value in athletes, and statistical methods for longitudinal data are required to identify meaningful changes within an athlete. Data quality is often compromised by poor pre-analytic controls in sport settings. The biotechnology industry is rapidly evolving, providing new technologies and methods, some of which may be well suited to athlete applications in the future. This review provides current perspectives, limitations and recommendations for sports science and sports medicine practitioners using blood profiling and monitoring for nutrition and performance purposes.
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Wearable physiological systems and technologies for metabolic monitoring.
Gao, W, Brooks, GA, Klonoff, DC
Journal of applied physiology (Bethesda, Md. : 1985). 2018;(3):548-556
Abstract
Wearable sensors allow continuous monitoring of metabolites for diabetes, sports medicine, exercise science, and physiology research. These sensors can continuously detect target analytes in skin interstitial fluid (ISF), tears, saliva, and sweat. In this review, we will summarize developments on wearable devices and their potential applications in research, clinical practice, and recreational and sporting activities. Sampling skin ISF can require insertion of a needle into the skin, whereas sweat, tears, and saliva can be sampled by devices worn outside the body. The most widely sampled metabolite from a wearable device is glucose in skin ISF for monitoring diabetes patients. Continuous ISF glucose monitoring allows estimation of the glucose concentration in blood without the pain, inconvenience, and blood waste of fingerstick capillary blood glucose testing. This tool is currently used by diabetes patients to provide information for dosing insulin and determining a diet and exercise plan. Similar technologies for measuring concentrations of other analytes in skin ISF could be used to monitor athletes, emergency responders, warfighters, and others in states of extreme physiological stress. Sweat is a potentially useful substrate for sampling analytes for metabolic monitoring during exercise. Lactate, sodium, potassium, and hydrogen ions can be measured in sweat. Tools for converting the concentrations of these analytes sampled from sweat, tears, and saliva into blood concentrations are being developed. As an understanding of the relationships between the concentrations of analytes in blood and easily sampled body fluid increases, then the benefits of new wearable devices for metabolic monitoring will also increase.
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Added value of hepcidin quantification for the diagnosis and follow-up of anemia-related diseases.
Lefebvre, T, Lasocki, S, Fénéant-Thibault, M, Lamy, PJ, Cunat, S, Ropert-Bouchet, M, Aguilar-Martinez, P, Lehmann, S, Delaby, C
Annales de biologie clinique. 2017;(1):9-18
Abstract
Iron homeostasis is based on a strict control of both intestinal iron absorption and iron recycling through reticulo-endothelial system. Hepcidin controls the iron fluxes in order to maintain sufficient iron levels for erythropoietic activities, hemoproteins synthesis or enzymes function, but also to limit its toxic accumulation throughout the body. Hepcidin expression is regulated by various stimuli: inflammation and iron stimulate the production of the peptide, while anemia, erythropoiesis and hypoxia repress its production. Regulation of hepcidin expression is not so simple in complex pathological situations such as hemolytic anemia, cancer or chronic inflammation. Serum hepcidin quantification in association with the diagnostic tests currently available is quite promising for the diagnosis or the follow-up of anemia in those conditions. This study is part of the working group « Clinical interests of hepcidin quantification » of the Société française de biologie clinique.
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How to Monitor and Advise Vegans to Ensure Adequate Nutrient Intake.
Fields, H, Ruddy, B, Wallace, MR, Shah, A, Millstine, D, Marks, L
The Journal of the American Osteopathic Association. 2016;(2):96-9
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How to monitor the brain in septic patients?
Oddo, M, Taccone, FS
Minerva anestesiologica. 2015;(7):776-88
Abstract
Brain injury is frequently observed after sepsis and may be primarily related to the direct effects of the septic insult on the brain (e.g., brain edema, ischemia, seizures) or to secondary/indirect injuries (e.g., hypotension, hypoxemia, hypocapnia, hyperglycemia). Management of brain injury in septic patients is first focused to exclude structural intracranial complications (e.g., ischemic/hemorrhagic stroke) and possible confounders (e.g., electrolyte alterations or metabolic disorders, such as dysglycemia). Sepsis-associated brain dysfunction is frequently a heterogeneous syndrome. Despite increasing understanding of main pathophysiologic determinants, therapy is essentially limited to protect the brain against further cerebral damage, by way of "simple" therapeutic manipulations of cerebral perfusion and oxygenation and by avoiding over-sedation. Non-invasive monitoring of cerebral perfusion and oxygenation with transcranial Doppler (TCD) and near-infrared spectroscopy (NIRS) is feasible in septic patients. Electroencephalography (EEG) allows detection of sepsis-related seizures and holds promise also as sedation monitoring. Brain CT-scan detects intra-cerebral structural lesions, while magnetic resonance imaging (MRI) provides important insights into primary mechanisms of sepsis-related direct brain injury, (e.g., cytotoxic vs. vasogenic edema) and the development of posterior reversible encephalopathy. Together with EEG and evoked potentials (EP), MRI is also important for coma prognostication. Emerging clinical evidence suggests monitoring of the brain in septic patients can be implemented in the ICU. The objective of this review was to summarize recent clinical data about the role of brain monitoring - including TCD, NIRS, EEG, EP, CT, and MRI - in patients with sepsis and to illustrate its potential utility for the diagnosis, management and prognostication.
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Measuring breath acetone for monitoring fat loss: Review.
Anderson, JC
Obesity (Silver Spring, Md.). 2015;(12):2327-34
Abstract
OBJECTIVE Endogenous acetone production is a by-product of the fat metabolism process. Because of its small size, acetone appears in exhaled breath. Historically, endogenous acetone has been measured in exhaled breath to monitor ketosis in healthy and diabetic subjects. Recently, breath acetone concentration (BrAce) has been shown to correlate with the rate of fat loss in healthy individuals. In this review, the measurement of breath acetone in healthy subjects is evaluated for its utility in predicting fat loss and its sensitivity to changes in physiologic parameters. RESULTS BrAce can range from 1 ppm in healthy non-dieting subjects to 1,250 ppm in diabetic ketoacidosis. A strong correlation exists between increased BrAce and the rate of fat loss. Multiple metabolic and respiratory factors affect the measurement of BrAce. BrAce is most affected by changes in the following factors (in descending order): dietary macronutrient composition, caloric restriction, exercise, pulmonary factors, and other assorted factors that increase fat metabolism or inhibit acetone metabolism. Pulmonary factors affecting acetone exchange in the lung should be controlled to optimize the breath sample for measurement. CONCLUSIONS When biologic factors are controlled, BrAce measurement provides a non-invasive tool for monitoring the rate of fat loss in healthy subjects.
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[Accelerometer description as a method to assess physical activity in different periods of life; systematic review].
Aguilar Cordero, MJ, Sánchez López, AM, Guisado Barrilao, R, Rodríguez Blanque, R, Noack Segovia, J, Pozo Cano, MD
Nutricion hospitalaria. 2014;(6):1250-61
Abstract
INTRODUCTION The accelerometer is shown as one of the most accurate techniques in recording and saving the amount and level of physical activity, by each person in a given period of time. AIMS This review aims to describe and analyze the main items that use this method to assess physical activity. METHODS The review articles were identified through the following specialized Internet browser: SCOPUS, PUBMED, GOOGLE SCHOLAR, those were selected for inclusion with a total of 56 items. The validity of the articles was given by the degree of evidence demonstrated by describing the recommendations and the applicability to our context. This review has considered studies evaluating physical activity through accelerometers. RESULTS The results show that this method can be used in ages 3 to 90 years. It can also be used in subjects with overweight/obesity, articulation injuries, Down syndrome (just children), autism and people with psychological problems. Studies in pregnant women show satisfactory results. CONCLUSION The literature reviewed provides the accelerometer as a reliable and effective method to assess physical activity.
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Diagnostic performance of fluorine-18-fluorodeoxyglucose positron emission tomography in the postchemotherapy management of patients with seminoma: systematic review and meta-analysis.
Treglia, G, Sadeghi, R, Annunziata, S, Caldarella, C, Bertagna, F, Giovanella, L
BioMed research international. 2014;:852681
Abstract
OBJECTIVE To meta-analyze published data about the diagnostic performance of fluorine-18-Fluorodeoxyglucose ((18)F-FDG) positron emission tomography (PET) and PET/computed tomography (PET/CT) in the postchemotherapy management of patients with seminoma. METHODS A comprehensive literature search of studies published through January 2014 on this topic was performed. All retrieved studies were reviewed and qualitatively analyzed. Pooled sensitivity and specificity, positive and negative predictive values (PPV and NPV), accuracy, and area under the summary ROC curve (AUC) of (18)F-FDG-PET or PET/CT on a per examination-based analysis were calculated. Subgroup analyses considering the size of residual/recurrent lesions were carried out. RESULTS Nine studies including 375 scans were selected. The pooled analysis provided the following results: sensitivity 78% (95% confidence interval (95% CI): 67-87%), specificity 86% (95% CI: 81-89%), PPV 58% (95% CI: 48-68%), NPV 94% (95% CI: 90-96%), and accuracy 84% (95% CI: 80-88%). The AUC was 0.90. A better diagnostic accuracy of (18)F-FDG-PET or PET/CT in evaluating residual/recurrent lesions >3 cm compared to those <3 cm was found. CONCLUSIONS (18)F-FDG-PET and PET/CT were demonstrated to be accurate imaging methods in the postchemotherapy management of patients with seminoma; nevertheless possible sources of false-negative and false-positive results should be considered. The literature focusing on this setting still remains limited and cost-effectiveness analyses are warranted.