AU2003100555A4 - Laryngeal mask airway - Google Patents

Description

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AUSTRALIA

PATENTS ACT 1990 COMPLETE SPECIFICATION FOR AN INNOVATION PATENT

ORIGINAL

Name of Applicant: Actual Inventor: Agent and Address for Service: Invention Title: Ti-Li Chang Ti-Li Chang MADDERNS, 1 st Floor, 64 Hindmarsh Square, Adelaide, South Australia, Australia LARYNGEAL MASK AIRWAY The following statement is a full description of this invention, including the best method of performing it known to us.

LARYNGEAL MASK AIRWAY 1. Field of the Utility Model The present utility model relates to a laryngeal mask airway for use with patients who are not able to breathe, and more particularly to a laryngeal mask airway that is efficient and convenient to use.

2. Description of Related Art With reference to Figs. 5 and 6, a conventional laryngeal mask airway in accordance with the prior art comprises an airway tube a laryngeal mask (70) and a laryngeal mask inflation tube (74).

The airway tube (60) is a large-bore tube made of resilient plastic material and has one end connected to the laryngeal mask The laryngeal mask (70) is teardrop-shaped and divided into a curved bottom face (not numbered) and a bladder (72) around the curved bottom face.

Multiple ventilation holes (71) are defined in the curved bottom face to connect the laryngeal mask (70) to the airway tube The bladder (72) is inflatable and has a distal pointed end (not numbered) and a rear obtuse end (not numbered). The laryngeal mask inflation tube (74) has two ends (not numbered). One end connects to the rear obtuse end of the bladder The other end of the laryngeal inflation tube (74) is a free end. An inflation indictor balloon (76) with a valve (77) is attached to the free end.

When the laryngeal mask airway is used to allow a patient to breathe, the laryngeal mask (70) is carefully flattened against the esophagus and the the pointed end of the bladder (72) is pushed into the esophagus until the ventilation holes (71) communicate with the larynx of the patient. With the bladder (72) around the opening to the larynx, a syringe (not shown) connects to the valve (77) to inject air into the bladder (72) via the laryngeal mask inflation line (74) to make the bladder (72) inflate. Thereby, no gap is formed between the bladder (72) and the larynx, and anesthetic gas can be injected into the lungs of the patient without any gas leakage. Meanwhile, the inflation indicator balloon (76) reflects the degree to which the bladder (72) is inflated so that medical personnel can observe and adjust the inflation of the bladder (72) as necessary.

However, the laryngeal mask airway still has the following drawbacks.

1. The bladder (72) usually has a pressure of 60-120cm H 2 0 when the bladder (72) is inflated with 20-30 cc. of air. Under this pressure, the mucous membrane of the larynx is easily damaged thereby causing ulceration of the larynx. If the pressure is reduced, the bladder (72) does not seal the larynx well, and the anesthetic gas easily escapes through the gaps.

2. The bladder (72) easily refolds at the pointed end when pressed against the esophagus. The refolded portion of the bladder (72) makes the patient uncomfortable, can cause the patient to reflexively vomit, which displaces the laryngeal mask airway from the necessary position guide the anesthetic gas to the lungs, thereby allowing the gas to escape.

3. The ventilation holes (71) in the mask (70) are covered completely or partially by epiglottis. Thus, the anesthetic gas cannot flow freely into the lungs.

4. The airway tube (60) and the laryngeal mask inflation tube (74) are separated so that the laryngeal mask inflation tube (74) has to be carefully manipulated when the laryngeal mask airway insert into the esophagus of the patient and can cause troublesome operational problems.

The present utility model has arisen to mitigate and/or obviate the disadvantages of the conventional laryngeal mask airway.

The main objective of the present utility model is to provide an improved laryngeal mask airway that is easily operated and efficiently conducts anesthetic gas into the larynx and ultimately the lungs of a patient.

Further benefits and advantages of the present utility model will become apparent after a careful reading of the detailed description with appropriate reference to the accompanying drawings.

Fig. 1 is a perspective view of a laryngeal mask airway in accordance with the present utility model; Fig. 2 is a cross-sectional side plan view of the laryngeal mask airway along line 2-2 in Fig. 1; Fig. 3 is a top plan view of the laryngeal mask airway in Fig. 1; Fig. 4 is an operationally side plan view of the laryngeal mask airway inserted into the esophagus and over the larynx of a patient; Fig. 5 is a perspective view of an conventional laryngeal mask; and Fig. 6 is an operational side plan view of the conventional laryngeal mask airway inserted into the esophagus and over the larynx of a patient.

With reference to Figs 1, 2 and 3, a laryngeal mask airway in accordance with the present utility model comprises a dual-airway tube a laryngeal mask (20) and a laryngeal mask inflation indicator device The dual-airway (10) has a connecting end and is composed of a primary tube (12) with an inner wall and a secondary tube (14) combined with the primary tube The primary tube (12) is a large-bore tube made of resilient plastic material and communicates with the laryngeal mask at the connecting end. The secondary tube (14) is formed inside walls of the primary tube (12) and emerges from the primary tube (12) a distance from laryngeal mask (20) to connect to the inflation indicator device The laryngeal mask (20) is teardrop-shaped to adapt to the larynx and is divided into a curved bottom face (not numbered) adjacent to the primary tube (12) and a bladder (24) around the curved bottom face. An opening (22) is defined in the curved bottom face to communicate with the primary tube (12) and at least one rib (26) radially and longitudinally projects from the inner wall of the primary tube (12) near the opening (22).

The bladder (24) having a pointed end and a rear obtuse end is made of soft material such as polyvinyl chloride (PVC) and has a tongue (242) extending forward from the pointed end of the bottom face inside the bladder The secondary tube (14) is attached to, communicates with and inflates the bladder (24) by a syringe connected to the inflation indicator device (30) via the secondary tube (14).

The inflation indicator device (30) connected to the secondary tube (14) is conventional. To avoid unnecessary repetition of known knowledge and techniques, no further description of the inflation indicator device (30) is provided.

With reference to Fig. 4, the laryngeal mask airway has the following advantages: 1. The tongue (242) at the pointed portion inside the bladder (24) prevents the bladder (24) from refolding at the pointed portion when the laryngeal mask airway flattens inside the esophagus of the patient.

Additionally, the bladder (24) made of PVC is soft to reduce the likelihood of larynx ulceration caused from undue pressing on the larynx.

2. The dual-airway tube (10) combines the primary tube (12) and the secondary tube (14) and simplifies these tubes (12, 14) into an integral tube.

Therefore, medical personnel do not have a cumbersome inflation tube (74) io of the conventional laryngeal mask airway to manipulate and insertion and operation of the laryngeal mask airway is much easier.

3. The at least one rib (26) longitudinally projecting from the inner wall of the primary tube (12) near the opening (22) keep the epiglottis from blocking the airway opening. The anesthetic gas is allowed to flow smoothly under the epiglottis, around the at least one rib (26) and into the body of the patient.

Although the utility model has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the utility model as hereinafter claimed.

Claims (4)

1. A laryngeal mask airway adapted to be positioned over the larynx of a patient, and comprising: a dual-airway (10) composed of a primary tube (12) and a secondary tube (14) combined with the primary tube the secondary tube (14) having a first end and a second end; a mask (20) adapted to cover the larynx and divided into a curved bottom face adjacent to the primary tube (12) and an inflatable bladder (24) with a pointed end around the curved bottom face that is connected to the first end of the secondary tube the mask (20) having an opening (22) defined in the curved bottom face to communicate with the primary tube (12); and an inflation indicator device (30) connecting to the second end of the secondary tube (14); wherein the improvements of the laryngeal mask airway comprise: at least one ribs (26) longitudinally formed inside the primary tube (12) near the opening (22) and adapted to prevent the epiglottis from covering the opening (22) so gases can be transmitted into and out of the patient; and a tongue (242) extending inside the bladder (24) at the pointed end to prevent the bladder (24) from refolding.

2. The laryngeal mask airway as claimed in claim 1, wherein two ribs (242) are formed inside the primary tube (12).

3. The laryngeal mask airway as claimed in claim 1, wherein the secondary tube (14) is embedded inside walls of the primary tube (12).

4. The laryngeal mask airway as claimed in claim 1, wherein the inflation indicator device (30) is an inflation indictor balloon (76) with a valve (77). The laryngeal mask airway as claimed in claim 1, wherein the bladder (24) is made of polyvinyl chloride (PVC). Dated this 11th day of July, 2003. Ti-Li Chang By his Patent Attorneys MADDERNS C 7 Ast