LuSi ,our Neonatal Lung Simulator ,is world's first autonomous and advance baby lung simulator with real-time artificial intelligence . To train clinicians in the assessment of pulmonary function and responds to treatment without operator's intervention . It can simulate pathologies like RDS, lung collapse, weak muscular activity, pneumothorax , airway obsctruction,etc. LuSi responds to treatment without operator intervention and can simulate pathologies like RDS, lung collapse, weak muscular activity, pneumothorax, airway obstruction, etc. Models based on scientific literature, for example Latzin et.al. Lung Volume, Breathing Pattern and Ventilation Inhomogeneity in Preterm and Term Infants.
Use the Vital Signs Monitor window to display the results of treatment in real-time. Include pre-ductal and arterial pulse oximetry. Configure the monitor to match the device of your unit. Modify technical features of monitors, for example the rise time of capnometers, to teach potential and limitations for use in neonates.
The design and selection of pathologies is controlled by LuSiLIFE, a touch screen enabled, pathology building and execution program. Execution of pre assembled cases, loading of patient case libraries, on-the-fly changes, notes taking and complete data recording for later analysis
Hardware : LuSi is shipped in a flight case ready to be used, complete with rechargeable batteries, battery charger and software.
Software : The windows based scenario building and editing software LuSiLIFE runs on almost all laptops and communicates with LuSi via Bluetooth.
Vital Signs Monitor : Vital signs monitor is created by simply adding a second monitor to the laptop and expanding the display. NOTE: Laptop and external monitor are not part of the delivery!
To name few Applications of respiratory therapy without risk to patients:
Programmable airway resistance
Programmable total compliance and chest wall compliance
Non-linear Pv curves
Make the lungs recruitable or non-recruitable
Change cardiac output
Create true shunt To create persistent pulmonary hypertension
Programmable PaCO2 to mimic central respiratory control
Programmable inspiratory effort
to create any patte
rn of spontaneous breathing
Change work of breathing
programmable diffusion factor
Programmable dead space
Programmable O2 dissociation curve
Create metabolic alkalosis or acidosis
Add movement artifacts
Create PtcCO2 Bias