Clinical Research Directory

The Effect of Respiratory Challenge on the BOLD Signal

The purpose of this research study is to better understand how blood flow and metabolism are different between normal controls and patients with disease. The investigators will examine brain blood flow and metabolism using magnetic resonance imaging (MRI). The brain's blood vessels expand and constrict to regulate blood flow based on the brain's needs. The amount of expanding and contracting the blood vessels can do varies by age. The brain's blood flow changes in small ways during everyday activities, such as normal brain growth, exercise, or deep concentration. Significant illness or physiologic stress may increase the brain's metabolic demand or cause other bigger changes in blood flow. If blood vessels are not able to expand to give more blood flow when metabolic demand is high, the brain may not get all of the oxygen it needs. In less extreme circumstances, not having as much oxygen as it wants may cause the brain to grow and develop more slowly than it should. One way to test the ability of the blood vessels to expand is by measuring blood flow while breathing in carbon dioxide (CO2). CO2 causes blood vessels in the brain to dilate without increasing brain metabolism. The study team will use a special mask to control the amount of oxygen and carbon dioxide patients breath in so that we can study how their brain reacts to these changes. This device designed to simulate carbon dioxide levels achieved by a breath-hold and target the concentration of carbon dioxide in the blood in breathing patients. The device captures exhaled gas and provides an admixture of fresh gas and neutral/expired gas to target different carbon dioxide levels while maintaining a fixed oxygen level. The study team will obtain MRI images of the brain while the subjects are breathing air controlled by the device.

End Tidal Carbon Dioxide Concentration and Depth of Anesthesia in Children

Carbon Dioxide (CO2) is a by-product of metabolism and is removed from the body when we breathe out. High levels of CO2 can affect the nervous system and cause us to be sleepy or sedated. Research suggests that high levels of CO2 may benefit patients who are asleep under anesthesia, such as by reducing infection rates, nausea, or recovery from anesthesia . CO2 may also reduce pain signals or the medication required to keep patients asleep during anesthesia; this has not been researched in children. During general anesthesia, anesthesiologists keep patients asleep with anesthetic gases or by giving medications into a vein. These drugs can depress breathing; therefore, an anesthesiologist will control breathing (ventilation) with an artificial airway such as an endotracheal tube. Changes in ventilation can alter the amount of CO2 removed from the body. The anesthesiologist may also monitor a patient's level of consciousness using a 'Depth of Anesthesia Monitor' such as the Bispectral Index (BIS), which analyzes a patient's brain activity and generates a number to tell the anesthesiologist how asleep they are. The investigator's study will test if different levels of CO2 during intravenous anesthesia are linked with different levels of sedation or sleepiness in children, as measured by BIS. If so, this could reduce the amount of anesthetic medication the child receives. Other benefits may be decreased medication costs, fewer side effects, and a positive environmental impact by using less disposable anesthesia equipment.