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This study is being done to learn more about energy needs and muscle function during treatment for bladder cancer. These insights can help improve future patient care. The study team found in a previous study that resting energy can be different than what estimates show. Patients with bladder cancer are known to suffer a decline in physical resilience over time. Monitoring patients to understand these changes better could help design future treatments with these vulnerabilities in mind.
The overarching aim of this proposal is to examine the feasibility of the Q-NRG+ indirect calorimetry device and its agreement with (Vmax) Encore indirect calorimetry device in mechanically ventilated children. The overall hypothesis of this study is that the Q-NRG+ will provide minute-to-minute oxygen consumption (VO2) and carbon dioxide production (CO2) measurements that are in agreement with those obtained by the standard indirect calorimetry device currently used at our institution (Vmax Encore).
The overarching aim of this research is to study the effects of caloric content and timing of meals on measures of postprandial metabolism and cardiovascular response 1. Determine the effect of caloric content on measures of postprandial metabolic flexibility and pulse wave analysis to a mixed meal challenge. 2. Determine the effect of meal timing on measures of postprandial metabolic flexibility and pulse wave analysis to a mixed meal challenge. Hypothesis: 1) that hypercaloric meals will result in significantly reduced indices of metabolic flexibility and pulse wave analysis as compared to eucaloric meals and 2) eucaloric meals consumed later in the day will result in significantly reduced metabolic flexibility and pulse wave analysis as compared to eucaloric meals consumed in the morning.
The purpose of this study is to determine if a particular method of providing nutrition improves the outcomes of patients in the intensive care unit (ICU) who have undergone abdominal surgery following trauma and would require nutrition delivered via the bloodstream (called total parenteral nutrition or TPN). The nutrition method being tested is a structured nutrition delivery plan, called the SeND Home pathway, that involves TPN, oral nutrition supplements, and the use of a device (called an indirect calorimeter or IC) to measure calorie needs. Participants will be randomly assigned (like the flip of a coin) to the SeND Home program or standard of care nutrition. In the SeND Home program, participants will receive TPN, followed by oral nutrition supplements (shakes) for 4 weeks after discharge. The control group will follow standard of care nutrition delivery that begins during ICU stay and concludes at hospital discharge. Participants in both groups will undergo non-invasive tests that measure how much energy (calories) they are using, body composition, and muscle mass and complete walking and strength tests, and surveys about quality of life.
The SKyRoCKeT Study (Surface-Knit and Reformulate CADENCE-Kids for Translation) will recruit a sex- and age-balanced sample of 360 young people 6-20 years of age to develop an integrative, physiologically-coherent age-cadence-log(metabolic equivalent, MET) surface-based model, reformulate the prior R21 CADENCE-Kids study (1; NCT01989104) by providing individualized, more precise, age-specific and coherent cadence-intensity thresholds, investigate additional differences by anthropometric factors, and translate cadence-intensity thresholds to over-ground walking. The SKyRoCKeT Study is an innovative critical step to provide a coherent, interpretable, objectively monitored step-based intensity metric to inform (inter)national physical activity (PA) guidelines by transforming currently vague guidelines of PA intensity into quantifiable PA recommendations that can be of widespread use, which clinicians, young people, parents, and researchers can integrate into preventive care management and action plans for personalized care. The SKyRoCKeT Study will allow for a user-friendly, interpretable metric to more accurately inform public health/behavioral interventions, assessments, analyses, school-based health and physical education curricula and programs, and public health messages for young people and their caregivers.
Excess fetal adipose tissue growth during intrauterine development increases future obesity risk. Development of brown adipose tissue, a highly thermogenic organ in utero, may affect postnatal energy expenditure, thus influencing obesity risk. This pilot research study is designed to understand the developmental origins of energy balance by examining maternal and neonatal factors that influence neonatal brown adipose tissue and to quantify its physiological relevance to energy expenditure in human neonates.