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The purpose of the study is to show if it's possible to use a special kind of ultrasound called backscatter quantitative ultrasound (bQUS) to check on a baby's lungs when the mother is 36 weeks pregnant. 12 participants will be on study for a single 30 minute ultrasound between 32 and 36 weeks of pregnancy.
This will be a randomized, placebo-controlled, double-blinded, pilot trial with two parallel groups (1:1 ratio) receiving either dexmedetomidine (initial bolus of 1 mcg/kg over 30 min after induction, followed by an infusion rate of 0.3 mcg/kg/hr that will be stopped 30-45 minutes before the end of the surgery or upon reaching maximum dose of 2mcg/kg, whichever comes first) or placebo (normal saline as a bolus followed by maintenance infusion at the same rate of the intervention group). Dexmedetomidine is frequently administered in thoracic surgery. Using local data from the Brigham and Women's Hospital, dexmedetomidine was used in a third of the thoracic procedures performed over the past three years. However, there is no consensus as to the optimal protocol of administration, therefore clinical practice is highly heterogeneous (bolus versus continuous infusion) and mostly depends on the preferences of anesthesia providers. In our institution, the dose of dexmedetomidine is typically 0.5 mcg/kg but varies based on attending preferences and experience. Given the heterogenous practices in dexmedetomidine administration, one of the objectives is to assess the feasibility of adhering to a dexmedetomidine protocol using an initial loading dose of 1 mcg/kg over 30 minutes after induction followed by a continuous infusion of 0.3 mcg/kg/hr. The infusion will stop 30-45 minutes prior to the end of surgery or once a maximum dose of 2mcg/kg has been achieved, whichever comes first. The control group will receive normal saline (similar bolus followed by maintenance infusion at the same rate of the intervention group).
Investigators will enroll 320 patients who will undergo non-cardiac surgery, receive supplemental oxygen via face mask, and will be on a continuous pulse oximetry monitor in the Post Anesthesia Care Unit (PACU). The enrollment criteria were adapted from a previous study that showed SpO2 values seriously underestimated the severity of post-operative hypoxemia in patients with and without specific risk factors for hypoxemia. Research personnel will screen and ensure that each subject meets the enrollment criteria, and the informed consent is properly executed. Upon arrival to the PACU, each subject will be fitted with oxygen mask containing the Linshom sensor, which will be connected to a Linshom monitor for data collection. A side stream capnography line will be connected to the same face mask and the capnography data will be collected on the Zoe Medical 740 SELECT™ monitor. Additionally, two pulse oximeters will be applied to the same hand (non- NIBP arm), one of which will be connected to a hospital monitor (SoC) and the other to a Zoe Medical 740 SELECT™ monitor. The Linshom and 740 SELECT™ monitors will collect data once every second. Research personnel will then initiate the Linshom CPRM baseline mode and begin recording any clinical intervention (e.g., medications, oxygen delivery change, and stimulation upon detection of changes in patient's condition) that is performed by the PACU staff, paying close attention to, and recording of time at which those interventions occurred. Data collection will be performed throughout the subject's entire PACU stay. The CPRM data collection will be performed passively while the patient is monitored via SoC and will not interfere with clinical interventions that may take place during the data collection. Clinical staff in the PACU will be blinded to the Linshom CPRM data as well as pulse oximetry (non-SOC monitor) and capnography data collected.
The purpose of this study is to evaluate the relationship between transdiaphragmatic pressure (Pdi) and diaphragm shear-wave elastography (SWE) during state-of-the-art respiratory muscle testing including volitional efforts (e.g., maximal inspiratory pressure, maximal expiratory pressure, Valsalva maneuver), as well as maximal phrenic nerve stimulation.
The goal of this clinical trial is to learn if using an incentive spirometer can reduce lung problems in people with advanced lung cancer who are receiving chemotherapy and radiation therapy. The main questions the study aims to answer are: Does using an incentive spirometer lower the chances of developing lung inflammation (pneumonitis)? Does it improve overall survival and quality of life? Participants will: Use an incentive spirometer, a device that helps with deep breathing, 10 times every hour while awake. Continue using the spirometer daily during treatment and for up to three months after treatment. Complete quality of life assessments at the start of the study and at 3, 6, and 12 months. Researchers will compare the results to see if the incentive spirometer helps reduce lung problems and improves participants\' well-being during and after their cancer treatment.