Carewell

The ventilator has been designed and developed with extensive research for acute management of respiratory care. The touch operated control panel offers ease of operation. The touch panel is very sensitive and offers fast response by using the Projected Capacitive Technology. The layout is logically grouped with graphics and other parameters. While the adaptive modes offer better patient ventilator synchrony, the Trends and the Respiratory Mechanics help for adequate and effective ventilation in critical situations. The respiratory Mechanics is based on very powerful and effective software which is formulated with “Least Square Fitting???(LSF) technique. It provides several data pertaining to ventilation even without using the manoeuvres of Inspiratory Hold. The data is very extensive that would help better respiratory management. It provides parameters like Inspiratory Peak-Flow, Expiratory Peak-Flow, Driving Pressure, Plateau Pressure, Auto PEEP, Static compliance, Inspiratory & Expiratory Resistances, Expiratory R*C, Pressure –time product (PTP), Mechanical Power imposed and Rapid Shallow Breathing Index (RSBI) The ventilator offers advanced modes of ventilation to treat patients who are very critical or show unstable pulmonary conditions. The waves and the loops of ventilation give an adequate pictorial insight to the operator. The respiratory mechanics adds data quantitively to act judiciously. Lung protective ventilation strategy can be planned based on these facilities. The different flow patterns provide the wide options to apply for varied lung complications. The monitored data is always handy at critical situations. The accelerating or the decelerating patterns can have different slopes. The cases of Pneumothorax, Atelectasis, COPD, or ARDS may be better treated using these variations. The trend chart helps modify ventilator strategy followed and visualize the status for early recovery. The NIV is very advanced using intelligent software for maintaining synchrony with patients. The fast response to inspiratory demand and the variable ETS has been the key. Complications associated with invasive ventilation may thus be avoided. Variable ETS has an important role during spontaneous breathing. It helps avoid asynchrony by using the proper duration of support for such breaths. Expressed in percent, higher ETS would withdraw the support early. Reverse would be the case for lower ETS. The Ventilator is very sleek and compact in design with a built-in air compressor. This compressor based on Peltier Effect for removal of moisture.