Surgery – Respiratory method or device – Means for supplying respiratory gas under positive pressure
Reexamination Certificate
2001-02-08
2003-06-03
Lo, Weilun (Department: 3761)
Surgery
Respiratory method or device
Means for supplying respiratory gas under positive pressure
C128S204180, C128S204250, C128S204160, C128S204270, C128S205240, C128S207150
Reexamination Certificate
active
06571796
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to the field of respiratory assist devices for respiratory care of a patient and, more particularly, to a respiratory system that automatically and variably on demand regulates the supply of a pressurized gas source to provide the appropriate pressure assist to the patient.
2. Background
Mechanical ventilatory support is widely accepted as an effective form of therapy and means for treating patients with respiratory failure. Ventilation is the process of delivering oxygen to and washing carbon dioxide from the alveoli in the lungs. When receiving ventilatory support, the patient becomes part of a complex interactive system which is expected to provide adequate ventilation and promote gas exchange to aid in the stabilization and recovery of the patient.
In those instances which a patient requires mechanical ventilation due to respiratory failure, a wide variety of mechanical ventilators are available. Most modern ventilators, i.e., respiratory systems, allow the clinician to select and use several modes of inhalation either individually or in combination via the ventilator setting controls that are common to the ventilators. These modes can be defined in three broad categories: spontaneous, assisted, or controlled. During spontaneous ventilation without other modes of ventilation, the patient breathes at his own pace, but other interventions may affect other parameters of ventilation including the tidal volume and the baseline pressure, above ambient, within the system. In assisted ventilation, the patient initiates the inhalation by lowering the baseline pressure by varying degrees, and then the ventilator “assists” the patient by completing the breath by the application of positive pressure. During controlled ventilation, the patient is unable to breathe spontaneously or initiate a breath, and is therefore dependent on the ventilator for every breath. During spontaneous or assisted ventilation, the patient is required to “work” (to varying degrees) by using the respiratory muscles in order to breath.
The work of breathing (the work to initiate and sustain a breath) performed by a patient to inhale while intubated and attached to the ventilator may be divided into two major components: physiologic work of breathing (the work of breathing of the patient) and breathing apparatus imposed resistive work of breathing. The breathing apparatus is properly defined as the endotracheal tube, the breathing circuit including an inhalation conduit, an exhalation conduit and a “Y” piece, the gas regulator, such as a ventilator, and may include a humidifier. The work required to spontaneously inhale through the breathing apparatus is the imposed resistive work of breathing (WOB
i
). The work of breathing can be measured and quantified in Joules/L of ventilation. In the past, techniques have been devised to supply ventilatory therapy to patients for the purpose of improving patient's efforts to breath by decreasing the work of breathing to sustain the breath. It is desirable to reduce the effort expended by the patient since a high work of breathing load can cause further damage to a weakened patient or be beyond the capacity or capability of small or disabled patients.
In conventional respiratory systems, pressure required to inflate the lungs of a patient connected to a life-support mechanical ventilator is typically measured within the breathing circuit from one of three conventional sites: the inspiratory conduit; the expiratory conduit; or the “Y” piece which is connected to both the inspiratory conduit and the expiratory conduit. Conventionally, at the onset of spontaneous inhalation in the pressure support ventilation (PSV) mode, for example, a pressure change is detected in the breathing circuit, the ventilator is triggered “on,” and lung inflation is assisted by positive pressure supplied by the ventilator. Pressure is then monitored/controlled from the pressure measuring site to ensure the preselected pressure is achieved, and with some ventilators, the rate of pressure rise over time is controlled based on preselected settings. At a specific pressure, for ventilatory support modes relying on pressure for cycling to the “off” phase, inhalation is terminated.
Inaccurate pressure measurements on the airways and lungs result from using the aforementioned conventional pressure measuring sites. During spontaneous breathing with continuous positive airway pressure (CPAP), for example, significant underestimations of pressure result compared with measuring tracheal pressure at the distal end of an endotracheal tube (P
T
). This is especially true when using narrow internal diameter endotracheal tubes and when peak spontaneous inspiratory flow demands are high. The narrower the tube and the greater the flow rate demand, the greater the discrepancy or inaccuracy between pressure measured at the “Y” piece and P
T
.
Due to inherently resistive components within the breathing circuit, in which the endotracheal tube is regarded as being the most significant resistor, the further from the trachea pressure is measured, the smaller the deviations in pressure that occur with CPAP. Small deviations during spontaneous inhalation may lead the clinician to erroneously conclude that the flow rate provided on demand by the ventilator is sufficient and the imposed resistive work of the breathing apparatus is minimal when, in fact, large deviations in pressure at the distal end of the endotracheal tube and a highly resistive workload imposed by the apparatus may be present.
Overestimations in tracheal airway pressure may result during mechanical inflation from the use of the conventional pressure measuring sites. Peak inflation pressure (PIP) generated during mechanical inflation varies directly with total resistance (imposed endotracheal tube resistance and physiologic airways resistance) and inversely with respiratory system compliance (C
rs
). PIP measured at the “Y” piece reflects the series resistance of the endotracheal tube and physiologic airways as well as Crs. Peak pressure measured in the trachea reflects physiologic resistance and Cr, only. Therefore, PIP measured at the “Y” piece may be greater than in the trachea. The narrower the internal diameter of the endotracheal tube and the greater the mechanical inspiratory flow rate, the more PIP measured at the “Y” piece overestimates pressure at proximate the distal end of the endotracheal tube. This becomes especially critical when dealing with intubated pediatric patients.
The conventional pressure measuring sites also compromise the responsiveness of the conventional respiratory systems to patient inspiratory efforts. This produces delays in triggering the supply of inspiratory assist “on” and cycling “off,” predisposing the patient to patient-respiratory system dysynychrony, and can dramatically increase the effort or work to inhale. Significantly less imposed work results from pressure triggering and controlling the respiratory system “on” at the distal end of the endotracheal tube compared with the conventional method of pressure triggering and controlling or by using Flow-By™. Flow-By™ is a method introduced by the Mallingckrodt Nellcor Puritan-Bennett Company that uses flow sensitivity to trigger the ventilator “on” instead of pressure sensitivity. Whether pressure triggering from inside the ventilator or using Flow-By™, an initial pressure drop across the endotracheal tube must be generated by the patient to initiate flow. This effort results in significant increases in imposed resistive work of breathing. Conventional respiratory systems introduce other more complex factors contributing to WOB
i
: the work to trigger the ventilator “on” (i.e., to initiate flow), the relative flow or pressure target used during the post trigger phase, and breath termination or cycling “off” criteria.
Thus, the design of conventional respiratory systems results in respiratory support systems that are predisposed to increase WOB
i
or have limited ability to de
Banner Michael J.
Blanch Paul Bradford
Erezo Darwin
Lo Weilun
Needle & Rosenberg, PC.
University of Florida
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