A tip part for a medical insertion vision device, a method of making the tip part, and a visualization system including the medical insertion vision device. The tip part includes an exterior housing having a distal front wall and a circumferential wall, the distal front wall and the circumferential wall enclosing an interior spacing having a camera compartment at a distal end and a potting compartment proximal of the camera compartment; a camera assembly positioned in the camera compartment, the camera assembly comprising an image sensor and a lens stack positioned distally of the image sensor, the image sensor having a proximal end; a sealing material that forms a seal that seals the camera compartment from the potting compartment; and a potting material in the potting compartment, the sealing material preventing the potting material from extending father distally than the proximal end of the image sensor.

A catheter having a distal end for insertion into a patient and including: a catheter tube enclosing at least a first catheter lumen and a vision lumen separated from the first catheter lumen, the first catheter lumen having a first distal opening at the distal end of the catheter; a window closing off a distal end of the vision lumen and having a planar interior window surface facing the vision lumen and a planar exterior window surface; and a vision device positioned in the vision lumen and having a vision module, such as a camera with an image sensor or an optical fibre, having an optical axis extending through the window; wherein the interior window surface and/or the exterior window surface is/are non-orthogonal with respect to the optical axis of the vision module, and the window surfaces are non-parallel.

Ventilator system with multiple inspiratory lumens is provided. The inspiratory lumens are configured so that separate inspiratory lumens provide inspiratory gas mixtures to separate portions of a patient's airways, for instance to separate lungs and/or bronchi. The ventilator system can include one or more expiratory lumens to evacuate expiratory gases from airways. The use of separate inspiratory lumen(s), with expiratory lumen(s), allows for functional separation of structural portions of the lungs, and maintenance of continuous or almost continuous flow through at least part of respiratory cycle via inspiratory and expiratory lumens. This can further reduce dead space and clear suspended therein diseases causative agents with improvement in outcomes, reduce risk of cross-contamination or cross-infection between different parts of airways, for example such as cross-infection from one lung lobe to another lobe or. The ventilator system allows for independent titration of PEEP, pCO.sub.2 and pO.sub.2 with no need for permissive hypercapnia.

Ventilator system with multiple inspiratory lumens is provided. The inspiratory lumens are configured so that separate inspiratory lumens provide inspiratory gas mixtures to separate portions of a patient's airways, for instance to separate lungs and/or bronchi. The ventilator system can include one or more expiratory lumens to evacuate expiratory gases from airways. The use of separate inspiratory lumen(s), with expiratory lumen(s), allows for functional separation of structural portions of the lungs, and maintenance of continuous or almost continuous flow through at least part of respiratory cycle via inspiratory and expiratory lumens. This can further reduce dead space and clear suspended therein diseases causative agents with improvement in outcomes, reduce risk of cross-contamination or cross-infection between different parts of airways, for example such as cross-infection from one lung lobe to another lobe or. The ventilator system allows for independent titration of PEEP, pCO.sub.2 and pO.sub.2 with no need for permissive hypercapnia.

Disclosed is a respiratory treatment apparatus that may be especially helpful for pediatric patients, though it may be useful for patients of all ages. In one embodiment, the apparatus comprises an endotracheal tube that is physically coupled to a bronchial blocker in a non-concentric fashion. In another embodiment, the apparatus comprises an endotracheal tube that is physically coupled to a steering balloon apparatus. The endotracheal tube, bronchial blocker, and/or steering balloon apparatus may be non-unitary components that are attachable to one another with one or more attachment structures, and once physically coupled, may be put to use. The endotracheal tube and bronchial blocker and steering balloon apparatus may be selected from a plurality of endotracheal tubes and bronchial blockers and steering balloon apparatus, to create an assembled apparatus that meets the needs of the patient.

A medical mechanical controlled balance ventilation single-lumen lung isolation catheter bridging spans trachea to bronchus and by-pass flow gas holes of wall, which has a intraluminal main trachea tube and a distal intraluminal bronchus tube in communication with one end of the intraluminal main trachea tube; a first opening is provided at a rear end of the distal intraluminal bronchus tube; a second holes opening zone having at least two holes is provided at a side wall of a lower end of the intraluminal main trachea tube; the transmural holes of the second holes opening zone are distributed along a same or different horizontal sectional surface or vertical sectional surface of a three dimensional space formed inside the intraluminal main trachea tube.

Methods and systems for targeting, accessing and diagnosing diseased lung compartments are disclosed. The method comprises introducing a diagnostic catheter with an occluding member at its distal end into a lung segment via an assisted ventilation device; inflating the occluding member to isolate the lung segment; and performing a diagnostic procedure with the catheter while the patient is ventilated. The proximal end of the diagnostic catheter is configured to be attached to a console. The method may also comprise introducing the diagnostic catheter into the lung segment; inflating the occluding member to isolate the lung segment; and monitoring blood oxygen saturation. The method may further comprise introducing the diagnostic catheter into the lung segment; determining tidal flow volume in the lung segment; determining total lung capacity of the patient; and determining a flow rank value based on the tidal flow volume of the lung segment and the total lung capacity.

Endotracheal devices and methods of using endotracheal devices are provided. The devices include a first elongated conduit having an internal dimension, a second elongated conduit having an external dimension less than the internal dimension of the first conduit, and a manipulation rod operatively mounted to the second conduit, where the manipulation rod allows an operator to move the second conduit within the first conduit. The manipulation rod may be used translate and/or rotate the second conduit within the first conduit. The first and second elongated conduits may be provided with inflatable cuffs to minimize the passage of fluids. Though aspects of the invention may be uniquely adapted for insertion through the trachea and into a bronchus, aspects of the invention may be used for other bodily passages.

A treatment system delivers a breathing gas and frozen ice or other particles (FSP) to a bronchus of a lung of a patient in order to induce hypothermia. The breathing gas and the FSP are usually delivered through separate lumens. Clogging of an FSP lumen can be inhibited by heating and/or cooling of the lumen. The temperature of exhaled gases or a body temperature may be measured, and a controller can adjust the duration or rate at which the ice particles are delivered in order to control the patient's core temperature based on the measured temperature.

A treatment system delivers a breathing gas and frozen ice or other particles (FSP) to a bronchus of a lung of a patient in order to induce hypothermia. The breathing gas and the FSP are usually delivered through separate lumens. Clogging of an FSP lumen can be inhibited by heating and/or cooling of the lumen. The temperature of exhaled gases or a body temperature may be measured, and a controller can adjust the duration or rate at which the ice particles are delivered in order to control the patient's core temperature based on the measured temperature.