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NZ737207B2 - Airway-tube holder - Google Patents
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NZ737207B2 - Airway-tube holder - Google Patents

Airway-tube holder Download PDF

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Publication number
NZ737207B2
NZ737207B2 NZ737207A NZ73720716A NZ737207B2 NZ 737207 B2 NZ737207 B2 NZ 737207B2 NZ 737207 A NZ737207 A NZ 737207A NZ 73720716 A NZ73720716 A NZ 73720716A NZ 737207 B2 NZ737207 B2 NZ 737207B2
Authority
NZ
New Zealand
Prior art keywords
airway
screw
tube holder
tube
thumb screw
Prior art date
Application number
NZ737207A
Other versions
NZ737207A (en
Inventor
Mathias Molden
Kluit Robert Provo
Original Assignee
Laerdal Medical As
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US14/718,768 external-priority patent/US10046130B2/en
Application filed by Laerdal Medical As filed Critical Laerdal Medical As
Publication of NZ737207A publication Critical patent/NZ737207A/en
Publication of NZ737207B2 publication Critical patent/NZ737207B2/en

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Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M16/00Devices for influencing the respiratory system of patients by gas treatment, e.g. ventilators; Tracheal tubes
    • A61M16/04Tracheal tubes
    • A61M16/0488Mouthpieces; Means for guiding, securing or introducing the tubes
    • A61M16/049Mouthpieces
    • A61M16/0493Mouthpieces with means for protecting the tube from damage caused by the patient's teeth, e.g. bite block
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M16/00Devices for influencing the respiratory system of patients by gas treatment, e.g. ventilators; Tracheal tubes
    • A61M16/04Tracheal tubes
    • A61M16/0488Mouthpieces; Means for guiding, securing or introducing the tubes
    • A61M16/0497Tube stabilizer
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M25/00Catheters; Hollow probes
    • A61M25/01Introducing, guiding, advancing, emplacing or holding catheters
    • A61M25/02Holding devices, e.g. on the body
    • A61M2025/0213Holding devices, e.g. on the body where the catheter is attached by means specifically adapted to a part of the human body
    • A61M2025/022Holding devices, e.g. on the body where the catheter is attached by means specifically adapted to a part of the human body specifically adapted for the mouth
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M25/00Catheters; Hollow probes
    • A61M25/01Introducing, guiding, advancing, emplacing or holding catheters
    • A61M25/02Holding devices, e.g. on the body
    • A61M2025/024Holding devices, e.g. on the body having a clip or clamp system
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M25/00Catheters; Hollow probes
    • A61M25/01Introducing, guiding, advancing, emplacing or holding catheters
    • A61M25/02Holding devices, e.g. on the body
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16BDEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
    • F16B2/00Friction-grip releasable fastenings
    • F16B2/02Clamps, i.e. with gripping action effected by positive means other than the inherent resistance to deformation of the material of the fastening
    • F16B2/06Clamps, i.e. with gripping action effected by positive means other than the inherent resistance to deformation of the material of the fastening external, i.e. with contracting action
    • F16B2/065Clamps, i.e. with gripping action effected by positive means other than the inherent resistance to deformation of the material of the fastening external, i.e. with contracting action using screw-thread elements
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16BDEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
    • F16B37/00Nuts or like thread-engaging members
    • F16B37/08Quickly-detachable or mountable nuts, e.g. consisting of two or more parts; Nuts movable along the bolt after tilting the nut
    • F16B37/0807Nuts engaged from the end of the bolt, e.g. axially slidable nuts
    • F16B37/0857Nuts engaged from the end of the bolt, e.g. axially slidable nuts with the threaded portions of the nut engaging the thread of the bolt by the action of one or more springs or resilient retaining members

Abstract

air-way tube holder (100) includes a face plate (102) having a v-shaped tube-receiving surface (114) that aligns with one side of an opening through the face plate, and a holding block (112), which is disposed near a second side of the opening. The holding block receives a thumb screw (130) and an engagement arm (142), the latter including a clamping head (144), which directly opposes the tube-receiving surface. The thumb screw is adapted to move the clamping head toward the tube-receiving surface to immobilize an airway tube therebetween, either by sliding the thumb screw (gross adjustment) or turning the thumb screw (fine adjustment). The thumb screw/clamping head is releasable by actuating a quick-release mechanism (694). The invention aims to provide an airway-tube holder with improved ergonomics. n engagement arm (142), the latter including a clamping head (144), which directly opposes the tube-receiving surface. The thumb screw is adapted to move the clamping head toward the tube-receiving surface to immobilize an airway tube therebetween, either by sliding the thumb screw (gross adjustment) or turning the thumb screw (fine adjustment). The thumb screw/clamping head is releasable by actuating a quick-release mechanism (694). The invention aims to provide an airway-tube holder with improved ergonomics.

Description

AIRWAY-TUBE HOLDER Field of the Invention The present invention relates to an apparatus for stabilizing an airway tube.
Background of the Invention Endotracheal tubes and laryngeal tubes establish and maintain an airway in a patient for the exchange of oxygen and carbon dioxide. These tubes are commonly used to mechanically ventilate a patient’s lungs during general esia and resuscitation. They are also used in critical-care and emergency-medicine settings.
Once inserted, the airway tube must be secured to t the tube from moving in patient’s throat during treatment. A variety of devices have been proposed for this purpose. Most of the recently proposed devices include a face plate having special adaptations for receiving and immobilizing the airway tube. In some of these devices, the face plate includes a ”v-” or ”u-” shaped tube-receiving surface that aligns with an opening through the face plate.
In use, after inserting an airway tube into a patient, a caregiver positions the face plate over the patient’s face. The n of the airway tube exiting the patient’s oral cavity is positioned near the tube-receiving e of the face plate. The ver then advances a clamping head towards the airway tube until they engage. Sandwiched between the clamping head and the tube-receiving surface, the airway tube is immobilized.
The clamping head is advanced using an actuating device, which the caregiver manipulates to move the clamping head into proper position. The most common entations of the actuating device are a thumb screw or a ratchet assembly. Some examples of airway-tube holders that orate a thumb screw are disclosed in U.S. Pat.
Nos. 5,402,776; 5,513,633; 6,067,985; and 063. Some examples of airway tube holders that use a ratchet assembly are sed in U.S. Pat. Nos. 6,010,484; 359 and in PCT Publication .
These and other prior-art airway tube holders have proven to be effective at immobilizing and stabilizing an airway tube. Yet they are, to varying degrees, uniformly 2 (followed by page 2A) cumbersome to use. As a consequence, the art would benefit from improvements in the ergonomics and other aspects of the design of -tube holders.
Summary of the Invention The present invention provides an airway-tube holder that overcomes some of the cks of the prior art. Specifically, the present invention provides an airway-tube holder for immobilizing an airway tube, the airway-tube holder having a screw, an engagement arm and a face plate configured to fit over a patient's oral cavity, the engagement arm having one degree of m, which is linear, the engagement arm having a clamping head disposed at a first end thereof, the face plate having a tubereceiving surface and a holding block, wherein the screw and the engagement arm are coupled to one r and disposed in parallel relation, wherein a first end of the screw attaches to the clamping head, and wherein the holding block receives the screw and the ment arm, and, when so received, the clamping head directly opposes the tubereceiving surface, the clamping head and the eceiving surface thus configured to immobilize the airway tube when in use, the screw having two degrees-of-freedom: linear and rotational, wherein the holding block ses at least one partial female thread for engaging threads of the screw, and a first member that supports the l female thread, wherein the holding block and the partial female thread are ally configured so that: (a) the screw slides past the partial female thread when the screw is subjected to a force having a first direction and being coaxial with a long axis of the screw, providing the linear degree-of-freedom; and (b) the screw is immobilized by the partial female thread when subjected to a force having a direction opposite to the first direction, providing the rotational degree-of-freedom, and wherein the first member has a configuration and location that results in generation of a counterforce that increases thread grip between the partial female threads and the threads of the screw in response to a force that results from incremental tightening of the screw. 2A (followed by page 3) The inventors studied conventional airway-tube holders to identify their shortcomings. The inventors came to realize that the actuating device (e.g. , thumb screw, ting mechanism, etc .) of most prior-art airway-tube holders impedes the ability of a caregiver to y immobilize an airway tube or quickly withdraw it from a patient.
In particular, having to rotate a thumb screw le times until a clamping head abuts an airway tube, or until it retracts therefrom, takes time. Furthermore, in some airway-tube holders, the screw or ting mechanism is loosely coupled to the face mask until it advances at least part of the way toward the airway tube. In such cases, it can be awkward to begin the process of ing the actuating device, such that two hands are required and time is lost. In medical emergencies, such delays are often more than a simple inconvenience; rather, they can be life threatening.
An airway-tube holder in accordance with the illustrative embodiment of the present invention addresses the aforementioned problems with: • improved ergonomics; • a thumb screw that can be advanced simply by pushing; • a thumb screw that can be released via a release feature, among other features.
In ance with the illustrative ment, the air-way tube holder comprises a face plate having a v-shaped tube-receiving surface, in the form of a notch, which aligns with one side of an opening through the face plate. The face plate includes a holding block, which is disposed near a second side of the opening. The holding block receives a thumb screw and an engagement arm. The engagement arm includes a clamping head, which directly opposes the tube-receiving surface. The thumb screw, which is operatively coupled to the ment arm, is adapted to move the clamping head toward 2016/052983 the tube-receiving surface. The clamping head and eceiving surface thus collectively form a clamp or adjustable aperture for immobilizing an airway tube.
The thumb screw is normally d to one or more complementary female screw s. However, by virtue of the arrangement of the female screw thread(s) with respect to the thumb screw, and as a consequence of the thumb screw’s thread profile, the thumb screw can be readily slid into position. This occurs without the need to take steps to actively disengage the female screw threads from the thumb screw. Once the clamping head of the engagement arm is in abutting or butting relation with the sidewall of an airway tube, the thumbscrew can then be turned by hand (i.e., threaded) to finely adjust the amount of pressure provided thereby against the sidewall of the tube.
When it is time to aw the airway tube, a quick-release mechanism of the airway-tube holder can be actuated. This mechanism affirmatively disengages the female screw thread(s) from the thumb screw, with the result that the thumb screw and engagement arm can be rapidly retracted from the airway tube.
In various embodiments, the face plate, thumb screw, engagement arm, and quick-release mechanism are structurally implemented so as to provide one or more of the following features or characteristics, among any : 0 e coarse and fine adjustment of clamping pressure; 0 slide and/or thread the clamping head into or out of position; 0 a mechanical stop for preventing damage to the quick-release mechanism; 0 surfaces to prevent ntal actuation of the quick-release mechanism; 0 facilitate smooth movement of the thumb screw upon release from an airway tube; 0 improve contact with an airway tube; 0 increase thread grip between the thumb screw and female threads as the thumb screw tightens against an airway tube; 0 adaptations for stabilizing the engagement arm; 0 facilitate gliding motion of engagement arm; and o a syringe grip for improved ergonomics when pushing the thumb screw.
Brief Description of the Drawings The ing is a brief description of the drawings, in which: depicts a front view of an airway-tube holder in accordance with the illustrative embodiment of the present invention. depicts a perspective view of the airway-tube holder of depicts an ”exploded” perspective view of the -tube holder of FIG. depicts a perspective view of the patient-facing surfaces of the airway- tube holder of depicts an embodiment of a thumbscrew of the airway-tube holder of FIG. depicts an embodiment of an engagement arm of the airway-tube holder of depicts a perspective view of a holding block of the -tube holder of s a top ctive view of the holding block of . depicts the thumb screw of and engagement arm of coupled to the holding block of FIGS. 8A and SB depict force diagrams. depict details about the trailing and leading e of the thumbscrew threads. depicts a perspective view of a second alternative embodiment of the airway-tube holder of FIG. QB depicts an exploded view of a portion of the airway-tube holder of FIG.
A depicts a top perspective view of the holding block of the airway-tube holder of . 3 depicts a bottom perspective view of the holding block of the airway- tube holder of .
A depicts a front view of a first alternative ment of the airway- tube holder of 3 depicts a top perspective view of the g block of the airway tube holder of A.
C depicts a bottom perspective view of the holding block of the airway tube holder of A.
Detailed Description Reference to the ”left” side or the ”right” side of an article ed in the accompanying drawings is to be tood as being from the ”perspective” of the article, not the . Reference to ”up, II II above,” ”down,” or ”below,” in conjunction with a drawing refers to a viewer’s perception of these directions when viewing the g, unless otherwise specified.
Overview ofAirway-Tube Holder.
Referring now to FIGs. 1AI lBI 2I and 3, in the illustrative embodiment, airway- tube holder 100 includes face plate 102, thumb screw 130, engagement arm 142, and padding 160.
Face plate 102 is dimensioned and configured to fit over a t’s oral cavity below the nose and above the chin. Face plate 102 has an arcuate form, wherein the patient-facing side (hereinafter ”inner surface”) of the face plate is curved to fit the contours of a patient’s face in the aforementioned region of the face. The foregoing description serves as a minimum definition of the term ”face plate,” as used in this disclosure and the appended claims. That is, at a minimum, a face plate must exhibit the aforementioned configuration.
In the illustrative embodiment, the face plate has a roughly oblong shape defined by upper perimeter 104 and (partial) lower perimeter 106. The fit to a t’s face is also facilitated, in the illustrative embodiment, by forming face plate 102 from a lightweight, 2016/052983 le, readily deformable material. Suitable materials include some thermoplastic materials, such as polypropylene, as well as others known to those skilled in the art.
In the illustrative embodiment, face plate 102 is monolithic in form (i.e., single- piece fabrication), but es a variety of surface structural features. For example, face plate 102 includes a wall or flange 110 that extends outwardly, orthogonal to the outward- facing side (hereinafter ”outer surface”) of the face plate. Although an ially continuous form in the illustrative embodiment, different portions of the wall are ated with different structures on face plate 102. For example, the right portion of wall 110 is a part of holding block 112 and the left portion of wall 110 defines tube-receiving surface 114.
In the illustrative embodiment in which face plate 102 is monolithic, all ures formed n/thereon comprise the same material (e.g., a flexible thermoplastic, etc.). In some other embodiments, face plate 102 is not a monolithic form; that is, one or more of the various structural features of face plate 102 can be integrated/attached thereto, by appropriate bonding techniques, etc. The various structures formed in/on face plate 102 are described in further detail below.
A salient feature of face plate 102 is channel 122, which has a roughly rectangular form and occupies the central portion of face plate 102. The channel extends from lower perimeter 106 of the face plate upwards about two-thirds of the way towards upper perimeter 104. Channel 122 is defined by: vertical edge 124 extending upwardly from left-side lower perimeter 106, tube-receiving surface 114 above vertical edge 124, horizontal upper edge 126 (which is the central portion of wall/flange 110), the left-most edge of holding block 112, and vertical edge 128, which is ed below the holding block and ates at right-side lower perimeter 106. Although it is desirable, as previously indicated, for face plate 102 to be flexible, in some embodiments, ning ribs are disposed on the inner surface of the portion of face plate 102 directly above channel 122 (see, e.g., C: stiffening ribs 1192). Since channel 122 effectively s a large portion of face plate 102, the ribs provide additional ural reinforcement for the face plate.
Tube-receiving surface 114, which in the illustrative embodiment has a v-shaped form, extends channel 122 rds of vertical edge 124. g block 112 is disposed directly across channel 122 from tube-receiving surface 114. In the illustrative embodiment, the holding block receives thumb screw 130 and ment arm 142, the latter including clamping head 144. As discussed later in this specification, the engagement arm and thumb screw are coupled to one another in such a way that the thumb screw has two s-of- freedom of motion (rotational and linear) yet the engagement arm has only one degree-of- freedom of motion (linear). The thumb screw is used to adjust the position the clamping head, so as to immobilize an airway tube or disengage therefrom.
By virtue of their ve positions, thumb screw 130, engagement arm 142, and eceiving surface 114 collectively define a clamp. And clamping head 144 and tube- receiving surface 114 collectively define an adjustable aperture 158 of the clamp that can immobilize an airway tube situated therein.
By way of explanation, in use of the device, an airway tube (not depicted) is first positioned in a patient’s mouth and throat. Airway-tube holder 100 is then positioned on the patient’s face below the nose and above the chin, with the airway tube sited in channel 122 close to tube-receiving e 114. Alignment feature 120, which in the illustrative ment is an embossed image of a ”nose,” facilitates proper face-plate-to-face alignment. In particular, the face plate is placed so that alignment feature 120 aligns with the patient’s nose. The inventors prefer to use an image of a nose, as opposed to language (i.e., ”nose”) or a non-descriptive alignment fiducial, to avoid language-comprehension issues and minimize any problems related to a caregiver’s lack-of-familiarity with airway- tube holder 100.
An adjustable strap (not depicted), which is attached to slots 116, secures airway-tube holder 100 around the patient’s neck. As sed in r detail later in this specification, a caregiver advances thumb screw 130 and engagement arm 142 toward the airway tube until clamping head 144 abuts the sidewall of the airway tube, thereby immobilizing the airway tube. Access-way 118 enables a caregiver to access other tubes, etc., for e, extending from the patient’s mouth.
Slots 116 for receiving the adjustable strap are disposed in -like regions 108, which are situated at the extreme left and right sides of face plate 102. The d regions deviate from the arcuate form of the main body of the face plate. That is, rather than following the inwardly curving profile of the main portion of face plate 102, flanges 108 bend ”outward” (forward) such that they fall in a plane that is substantially parallel to thumb screw 130 and engagement arm 142. Within flanges 108, slots 116 are canted such that the lower portion of each slot is laterally inward of the upper portion thereof. The inventors observed that when strap-holding slots are oriented vertically (i.e., straight up and down) as in the prior art, the strap often slips (assuming it is not positioned above the ears), sliding downward from its initial position toward the patient’s lower neck. This causes the strap to become slack with the result that the face plate will loosen. Although the airway tube will remain immobilized by whatever clamping mechanism is used in ction with the face plate, the tube will be free to move relative to the patient, which is unacceptable.
To address this problem, and unlike the prior art, slots 116 are canted as bed above.
This facilitates initially siting the strap at a lower on about the neck, such that the likelihood of slippage is significantly reduced.
Padding 160 is disposed on the inner surface of face plate 102 to provide comfort for the patient. The padding is typically foam. The g can be attached to face plate 102 via rivets (see, e.g., C: rivets 1194) that are integral thereto and extend from the inner surface thereof, such as disclosed in U.S. Pat. No. 8,360,063, which is orated by nce herein. Other s for attaching the padding to the inner surface of the face plate, as will occur to those skilled in the art, can suitably be used.
Airway-tube holder 100 also includes bite block 362, best viewed in The bite block, which extends from the inner surface of face plate 102, is essentially an extension of, and has the same form as, tube-receiving surface 114. Bite block 362 has two spaced-apart walls 364 and 366. This arrangement imbues bite block 362 with flexibility ient to enable it to be grasped by a patient’s teeth without affecting the airway tube mounted against it. depicts thumb screw 130. The thumb screw includes head 436, s 432, and coupler 440. In the illustrative embodiment, threads 432 have an asymmetric profile, unlike conventional .
As used in this disclosure and the appended claims, the term ”asymmetric,” when used to describe screw threads, means that the angle of inclination of one side of a thread is ent than the angle of inclination of the other side of the same thread. As used in this disclosure and the ed claims, the term ”leading side,” when ncing thread direction, refers to the side of the thread that ”leads” as thumb screw 130 is advanced toward eceiving surface 114. The term ”trailing side,” when referencing thread direction, refers to the side of the thread that ”trails” as thumb screw 130 is advanced toward tube-receiving surface 114. These terms retain this meaning when the screw is advanced in the reverse direction. That is, even though the ”trailing side” of the thread leads when the screw is moved away from tube-receiving surface 114, it maintains the designation ”trailing side.” In the illustrative embodiment, head 436 is knurled. The head includes retaining groove 438, which has an annular form and es end 556 of stem 550 (see of engagement arm 142. Coupler 440, which is al with threads 432, extends from forward surface 434 of thumb screw 130. In the illustrative embodiment, r 440 is implemented as two spaced-apart members that are enlarged at their free ends. The enlargement creates a shoulder on each member that functions as a catch when forced through an appropriately sized opening.
As will be appreciated by those skilled in the art, a different style of head (e.g., spade, wing, etc.) can be used in conjunction with thumb screw 130, as long as it includes (for airway-tube holder 100) a groove like groove 438 that receives the end of stem 550.
The thumb screw is made from a eight, relatively low-cost material that is robust enough for use in low- to medium-stress components. Suitable materials include some thermoplastics, such as s nylons, among other materials known to those skilled in the art.
As described later in conjunction with FIGs. 6, 7, and 8, as facilitated (but not necessitated) by its asymmetric threads, thumb screw 130 is slideable along one direction and locks in the other direction. depicts engagement arm 142. The engagement arm includes stem 550 and clamping head 144 disposed at one end thereof. Upper surface 552 of the stem has a convex profile and lower surface 554 thereof has a concave profile. This facilitates coupling end 556 of stem 552 to retaining groove 438 (see, e.g., ) in the head of thumb screw 130. Surface 547 of ng head 144 is curved to tate engagement with the ll of an airway tube. In the rative embodiment, ribs 548 are disposed on surface 547. As compared to a relatively larger planar surface such as surface 547, ribs 548, which in the illustrative embodiment have an arcuate shape matching the curve of surface 547, ensure positive contact with the sidewall of an airway tube and enable more pressure to be applied o. Opening 546 in clamping head 144 receives coupler 440 of thumb screw 130, snapping the two parts together. In some ments, all features of the engagement arm are made from the same material as thumb screw 130.
Holding Block.
FIGs. 6A, 63, and 7 provide r detail of holding block 112 and the manner in which thumb screw 130 and engagement arm 142 cooperate therewith. In conjunction with FIGs. 6A, 63, and 7, the terms ”above,” ”higher,” or ”outwardly of” mean ”further from the surface of face plate 102.” Conversely, the terms ”below,” ”lower,” or ”inwardly of” mean ”closer to the surface of face plate 102.” Referring now to , in the illustrative embodiment, holding block 112 has an approximately square perimeter, as defined by walls 610A, 6103, 610C, and 610D (collectively ”walls 610”). These walls are specific segments of lange 110. Walls 610A and 610C each have raised guard portion 670. These guard portions reduce the likelihood of inadvertent contact with plate member 690, the implications of which are discussed further below.
Walls 6103 and 610D each e openings 672. In the illustrative embodiment, these openings are circular and are dimensioned to receive thumb screw 130. Groove 676 is disposed in walls 6103 and 610D above opening 672 therein. Each groove 676 is defined by bottom surface 678 and sidewalls 680A and 6803. Grooves 676 are dimensioned and arranged to receive stem 550 of engagement arm 142. As a consequence, the separation between opposing sidewalls 680A and 6803 of each groove is slightly greater than the width of stem 550. Furthermore, since lower e 554 of stem 550 has a concave shape, bottom surface 678 of each groove has a complementary convex form. This facilitates smooth, g movement of stem 550 of engagement arm 142 within grooves 676.
With reference now to , in some embodiments, two -apart arms 684 depend from wall 6103 proximal to the base thereof (i.e., relatively closer to the surface of face plate 102). Arms 684 are angled outwardly and are capable of flexing, predominantly at the intersection with wall 6103. l female threads 686 span the gap n spaced-apart arms 684.
In the rative embodiment, partial female threads 686 comprise three partial threads, which es sufficient thread grip, when required, in conjunction with thumb- screw threads 432, preferably asymmetric, with they engage. In some other embodiments, female threads 686 comprise one or two partial threads, and in yet some further embodiments, more than three partial s are used. Using l partial threads, as opposed to a single thread, distributes the force applied by the thumb screw 130, permitting a less durable plastic to be used for the female threads.
As the descriptor ”partial” indicates, female threads 686 are not ”full” threads in the sense that they do not extend for grees of arc. As used in this description and appended claims, the term ”partial”, when used to reference a male or female screw thread, means a segment of thread that extends for less than 360-degrees of arc. In other words, the term ”partia In does not refer to the number of threads, but rather the circumferential extent of a thread. The icance of the use of partial female threads 686 is discussed in r detail later in this disclosure.
At the free end of each arm 684, arms 688 extend outwardly, rising above upper surface 682 of wall 610D. Plate member 690 is disposed on top of arms 688. Opening 696 is formed between arms 688 and below plate member 690. This opening, in conjunction with openings 672, permits passage of thumb screw 130 through holding block 112.
Gap 698 () is defined between upper surface 682 of wall 610D and the lower surface of plate member 690. As discussed further below, arms 684, arms 688, and plate member 690 collectively function as quick-release mechanism 694 for decoupling threads 432 of thumb screw 130 from partial female threads 686. Icon 692, which in the illustrative embodiment is embossed on the upper surface of plate member 690, is a pictorial entation of an open ”lock.” This is intended to indicate to a user that pressing plate member 690 will actuate the quick-release mechanism.
Referring now to FIGS. 4, 5, 6A, 63, and 7, to assemble airway-tube holder 100, thumb screw 130 is inserted through opening 672 in wall 610B, through opening 696 in quick-release mechanism 694, and through opening 672 in wall 610D. End 556 of stem 550 of engagement arm 142 is positioned in groove 676 of wall 610D and advanced across holding block 112 where it is received by groove 676 in wall 610B.
End 556 of stem 550 is advanced until it is received by annular retaining groove 438 in head 436 of the thumb screw. At the same time, opening 546 in clamp head 144 of the engagement arm receives coupler 440 (of thumb screw 130) to fixedly couple ment arm 142 to thumb screw 130. It is to be understood that the fabrication process described above can be reversed; that is, engagement arm 142 can be inserted into holding block 112 before thumb screw 130.
Engagement of Thumb Screw to Partial Female Threads.
As previously described, in the illustrative embodiment, threads 432 of thumb screw 130 have an asymmetric e and partial female threads 686 have a complementary ite) tric thread profile. Having an asymmetric profile of the ted directionality (i.e., the g side of the thread tapers from narrow to wider) facilitates pushing thumb screw 130 toward tube-receiving surface 114 with little resistance from partial female threads 686. Once in abutting or near abutting relation with the sidewall of an airway tube, a user can turn (i.e., thread) rather than push thumb screw 130, thereby fine-tuning the clamping force applied to an airway tube.
The asymmetry of threads 432 of thumb screw 130 facilitate the bi-functionality of the thumb screw (i.e., capable of sliding movement or threading movement) and improve its performance in that regard. In some other ments, however, thumb-screw threads 432 are symmetric and can still be slid over partial female s 686 (which are symmetric in embodiments in which the thumb-screw s are symmetric) as a consequence of the manner in which the partial female s are supported.
A particularly advantageous characteristic of the illustrative ment is that once thumb screw 130 meets resistance, such as when clamping head 144 of engagement device 142 presses against the sidewall of an airway tube, the thread grip increases as the thumb screw is entally tightened.
This is a result, in the illustrative embodiment, of a cal” offset and a ”horizontal” offset between the point at which arms 684 (which support partial female threads 686) are supported and the point of engagement between the male and female threads. This phenomenon is sed further below in conjunction with FIGs. 8A and 83, which depict force diagrams for two arrangements. For the analysis depicted in these Figures, it is assumed that arms 884A and 8843 are rigid and that all bending occurs at elastic- ”hinge” point 802, wherein bending the arms at elastic-hinge point 802 results in a restoring torque. depicts an arrangement in which there is a non-trivial ”horizontal” offset Oh, but essentially no cal” offset 0, between c-hinge point 802A and the point at which screw threads 832 and partial female s 886 engage one another.
The arrangement ed in includes wall 8103, which supports, at elastic- hinge point 802A, arm 884A. The arm supports partial female threads 886. A screw having threads 832, which are asymmetric in this embodiment, passes through an opening in wall 8103 and engages the female threads 886. The screw abuts airway tube 804.
The force applied by the screw on arm 884A is F, and the counterforce from the arm 884A is F’. Both force F and counterforce F’ are horizontal; that is, these forces have a ”zero angle” with respect to one another since there is no vertical offset 0, between the elastic- hinge point 802A and the point at which the male and female threads engage one another. (Although actually shows a small vertical offset 0v, for simplicity, the force is presented below assumes that there is no vertical offset.) As such, the vertical force from arm 884A to screw threads 832 (which is a on of the amount of upward pretension provided to arm 884A) is constant. As a consequence, the thread grip is dependent upon a sufficiently strong pretension in arm 884A. depicts an ement in which, in addition to a horizontal offset 0V, there is a non-trivial vertical offset 0, between elastic-hinge point 8023 and the point at which the male and female threads engage one another (hereinafter the ”thread- engagement point”).
The arrangement depicted in FIG. SB includes wall 8103, which supports, at elastic hinge 8OZB, arm 8843. The arm supports partial female threads 886. A screw having s 832, which are asymmetric in this embodiment, passes through an opening in wall 8103 and engages the female threads 886. The screw abuts airway tube 804.
The force analysis in this example, which shows a significant vertical offset 0, between the arm’s elastic-hinge point 8023 and thread-engagement point 887, is different from that of the zero-offset case depicted in . As depicted in FIG. SB, gh force F d by the screw is horizontal, the counterforce F’ from arm 8843 is not horizontal; that is, it is directed at a non-zero angle with respect thereto consistent with angle on (based on vertical offset 0, and horizontal offset Oh) between elastic hinge point 8023 and thread ment point 887. For purposes of illustration/analysis, thread-engagement point 887 is considered to be the intersection of the vertical midpoint of the threads and horizontal nt of the threads.
Counterforce F’ can be resolved into two scalar components F’xand F’y. al component F’y (and the ntal component F’x) of the counterforce increases with an se in force F. As a consequence, as the screw is tightened against airway tube 804, the thread grip (which results from the vertical counterforce) increases. Conversely, in the absence of a resistance such as that presented by airway tube 804, the screw can be pushed over the partial female threads, even though the male and female threads are initially engaged.
It will be appreciated by those skilled in the art that even if the arms that support the partial female threads are not rigid, such that bending occurs across the length of the arm (not solely at elastic hinge point 802), thread grip will increase per the ing analysis.
Regarding thread asymmetry/symmetry, it is notable that greater wear is expected to be experienced by both the male and female threads due to repeated pushing of the thumb screw for a thread profile that is relatively less asymmetric (relatively more ric) than in the illustrative embodiment. As previously indicated, in the illustrative embodiment, to facilitate ”sliding” of thumb screw 130 towards tube-receiving e 114, the leading side of the threads tapers from narrow (front edge) to wide (back edge).
Referring now to , which s a partial view of the arrangement depicted in FIG. SB, angle-of-inclination 0L3 of leading edge 833 of the screw threads 832 is in a range of about 5 to about 50 degrees, more preferably in a range of about 10 to 40 degrees, and most preferably within a range of about 15 to 30 degrees. For a given crest height, as angle-of-inclination (1.3 decreases, the length of the thread increases. As angle-of- inclination a3 increases, more noise is generated when the thumb screw is slid past the l female threads.
Angle-of-inclination or; of ng side 833 of the thumb screw’s threads 832 is typically in a range of about 0 to 15 degrees (i.e., wherein 0 s is ”vertical” in ).
Angle on (FIG. SB) of arm 884B should be greater than angle-of-inclination (12 so that the ability to immobilize the thumb screw is not dependent on the friction within the s.
It will be appreciated by those skilled in the art that for the scenario depicted in FIG. SB as well as in the illustrative embodiment, the vertical movement of the screw must be limited. That is, clearance between the outermost diameter of thumb-screw threads 432 (measured at the crest of a thread) and opening 672 must be limited to amount that is related to the pre-tension (i.e., upward bias) of the arms that support the female threads (i.e., arms 684 in the illustrative embodiment). In some embodiments, the gap is limited to 0.1 millimeters (mm). If the vertical tolerance for movement of the screw is greater than the pretension in the arms and the thread height, the arms will not be able to create any grip tension on the screw threads, such that unintentional sliding of the screw over the female threads is likely to occur. In accordance with embodiments of the invention, the only way to achieve no grip and no thread tension is to use the quick release mechanism.
Quick e Mechanism.
The pressure d against an airway tube by engagement arm umb screw 130 can be released in either of two ways. A caregiver can simply ”un-screw” thumb screw 130, turning head 436 counterclockwise. A much quicker way to e the engagement arm and thumb screw is to actuate quick-release mechanism 694.
Referring again to FIGs. 6A and 63, as previously mentioned, arms 684, arms 688, and plate member 690 collectively function as quick-release mechanism 694 for decoupling s 432 of thumb screw 130 from partial female s 686. The quick-release mechanism is actuated by pressing plate member 690. The plate member is coupled, via arms 688, to arms 684 that support partial female threads 686. Pressing plate member 690 therefore causes threads 686 to move downward. Since thumb screw 130 is constrained to lateral movement via openings 672, the downward movement of partial female threads 686 ages them from threads 432 of thumb screw 130. Once the female threads are disengaged, thumb screw 130 and engagement arm 142 can be slid away from the formerly immobilized airway tube.
As a uence of the directionality of asymmetric threads 432, in the case of movement away from an airway tube, the thumb screw cannot simply be slid over the female s as when the screw is being moved s a tube. This is because the threads will present an edge with a steep angle (i.e., in the range of about 75 to 90 degrees) to asymmetric partial female threads 686, which would substantially hinder or t movement of thumb screw 130 unless quick release mechanism 694 is actuated.
As best seen in , downward movement of plate member 690 is enabled by gap 698 between bottom surface of the plate member and top surface 682 of wall 610D.
Top surface 682 thus functions as a ical ”stop” to prevent excessive downward movement of arms 684. Repeated excessive movement could cause arms 684 to fail.
To implement the quick-release feature in a straightforward, uncomplicated manner, the female s cannot fully surround the male threads 432. For use with the illustrative embodiment, the arc length of female threads 686 should be less than 180 degrees, and ably about 90 degrees (i.e., one-quarter of the way around a circle).
Otherwise, the female threads would not fully disengage from the male threads.
The maximum permitted arc length is based on the dimensions of the thread as well as the distance that female threads 686 can move away from male threads 432. Based on these considerations, one skilled in the art will be able to calculate the maximum allowable length of arc for the female threads. Alternatively, simple experimentation can be used to determine a length of arc that provides the ite nce.
In the illustrative embodiment, the distance that female threads 686 can move away from the male threads is limited by the size of gap 698 between the bottom surface of plate member 690 and surface 682 of wall 610D. And the size of gap 698 is selected to ensure that thread-supporting arms 684 do not fail by exceeding their flexural limitations.
In light of the present teachings, those skilled in art will know how to e these factors when developing a design for partial female threads 686 and quick-release ism 694.
To facilitate smooth sliding movement of thumb screw 130 away from an airway tube, at least a portion of the perimeter of opening 672 in wall 610D at surface 673 includes chamfer 674.
First Alternative Embodiment FIGs. 11A through 11C depict airway-tube holder 1100. This embodiment of the airway-tube holder differs from airway-tube holder 100 in the particulars of the design of the holding block, but is otherwise cal. ically, in airway-tube holder 1100, holding block 1112 es only a single arm —arm 1184— for supporting partial female threads 1186. As in the previous embodiments, two arms 1188 are used to support the plate member 1190.
In this embodiment, arm 1184 includes a physical adaptation that es flexing at a single location on the arm; that is, the arm behaves as a rigid member and the physical adaptation es the elastic hinge with a ing torque upon bending, as discussed in FIGs. 8A-83. In the illustrative embodiment, the physical adaptation is a thinned region 1185 of arm 1184. The arm is more likely to flex in thinned region 1185 than elsewhere along the arm. This is arrangement is similar to a ”living” hinge, n a material is d or cut to allow rigid pieces to bend along the line of the ”hinge.” However, living hinges typically do not provide a restoring torque upon bending, wherein arm 1184 with thinned region 1185 will e such a restoring torque. For use in this disclosure and the appended claims, the term ”elastic living hinge” is used to refer to a living hinge that provides a restoring torque. Thinned region 1185 is located near the on of arm 1184 with wall 11103. In some other embodiments, other arrangements are used to emulate the functionality of a hinge to promote flexing of arm 1184 near wall 11103.
Second Alternative Embodiment FIGs. 9A, 93, 10A and 103 depict airway-tube holder 900, which is a first alternative embodiment of airway-tube holder 100. The primary distinctions between airway-tube holder 900 and airway-tube holder 100 pertain to the design of the holding block, quick-release mechanism, and engagement arm.
Referring now to FIGs. 9A and 93, airway-tube holder 900 includes face plate 902, thumb screw 930, and engagement arm 942. Padding, not depicted, is disposed on the 2016/052983 inner (patient-facing) surface of face plate 902. The shape of face plate 902 is similar to that of face plate 102.
Like face plate 102, face plate 902 includes a wall or flange 910 that extends outwardly, orthogonal to the outer surface of the face plate. Although an ially continuous form, different portions of wall 910 are associated with different structures on face plate 902. The right portion of wall 910 forms a part of g block 912 and the left portion of wall 110 defines tube-receiving surface 914.
The central portion of face plate 902 is occupied by channel 922, which has a roughly rectangular form like channel 122 of face plate 102. Tube-receiving surface 914, which has a v-shaped form, defines a portion of the left side of channel 922. Holding block 912 is ed directly across channel 922 from tube-receiving surface 914. The holding block receives thumb screw 930 and engagement arm 942, the latter including clamping head 944. As in airway-tube holder 100, the engagement arm and thumb screw of airway- tube holder 900 couple to one another in such a way that the thumb screw has two degrees-of-freedom of motion (rotational and linear) while the engagement arm has only one degree-of-freedom of motion (linear). ng head 944 and tube-receiving surface 914 collectively define a clamp or adjustable aperture 958 that can immobilize an airway tube situated therein.
Thumb screw 930 includes head 936, threads 932 (which have an asymmetric profile like threads 432), and coupler 940. The coupler, which is co-axial with threads 932, extends from the d surface of thumb screw 930.
Engagement arm 942 es stem 950 and clamping head 944 disposed at one end f. Unlike the stem of engagement arm 142, the upper surface and lower es of stem 950 are flat. Also unlike engagement arm 142, engagement arm 942 has coupling ring 957 disposed at end 956 of stem 950. The coupling ring receives threads 932 of thumb screw 930. This enables engagement arm 942 and thumb screw 930 to couple to one another. rmore, as in airway-tube holder 100, coupler 940 is received by hole 946 in clamping head 944, to secure the engagement arm and thumb screw to one another.
Surface 947 of clamping head 944 is curved to facilitate engagement with the sidewall of an airway tube. 2016/052983 FIGs. 10A and 103 depict further detail of holding block 912 and the manner in which thumb screw 930 and engagement arm 942 cooperate therewith.
Referring now to A, holding block 912 has an approximately square perimeter, as defined by walls 1010A, 10103, 1010C, and 1010D (collectively ”walls 1010”).
These walls are specific segments of wall/flange 910.
Near wall 10103, wall 1010A curves ”upward.” Near wall 1010A, wall 10103 is extended straight ”upward.” The extended portions of these two walls meet to create flared region 1011A. Flared region 10113 results from the same ed configuration, although in a ”downward” ion, of walls 1010C and 10103. The two flared regions 1011A and 10113 collectively define a ”syringe” grip for improved ergonomics when pushing thumb screw 930 toward tube-receiving region 914.
Walls 10103 and 1010D each include openings 1072. In the illustrative embodiment, these openings are circular and receive thumb screw 930. Groove 1076 is disposed in walls 10103 and 1010D ”inward” of opening 1072 therein. Each groove 1076 is defined by surface 1078 and sidewalls 1080A and 10803. Grooves 1076 are dimensioned and ed to receive stem 950 of engagement arm 942. As a uence, the separation between opposing sidewalls 1080A and 10803 of each groove is slightly r than the width of stem 950.
Two spaced-apart arms 1084 depend from wall 1010D proximal to the base thereof (i.e., relatively closer to the surface of face plate 902). Arms 1084 are angled outwardly and are capable of flexing, predominantly at the intersection with wall 1010D. As best seen in , arm 1088 extends outwardly from each arm 1084. Referring again to 3, l female threads 1086 span the gap between the two arms 1088. The partial female threads face ”inward,” since these threads are located outward of thumb screw 930.
Arms 1088 ue d, rising above walls 1010. Plate member 1090 bridges arms 1088. Plate member 1090 flares outward, continuing beyond walls 1010 in the direction of wall 10103. ing now to FIGs. 9A, 93, 10A, and 103, to assemble airway-tube holder 900, engagement arm 942 is positioned in grooves 1076 located at the ”bottom” of walls 10103 and 1010D, with clamping head 944 nearest to tube-receiving surface 914. Thumb screw 930 is inserted through ring 957 in engagement arm 942, inserted through opening 1072 in wall 10103, and though opening 1072 in wall 1010D. Opening 946 in clamping head 944 of the engagement arm receives coupler 940 of thumb screw 930 to fixedly couple engagement arm 942 to the thumb screw.
The asymmetric thread profile of threads 932 enable thumb screw 930 to be pushed toward tube-receiving e 914 with little resistance from partial female threads 1086, akin to the operation of thumb screw 130 of airway-tube holder 100. And, as in the illustrative embodiment, once clamping surface 944 is in abutting or near abutting relation with the sidewall of an airway tube, a user can turn (rather than push) thumb screw 930 to fine tune the clamping force applied to the airway tube.
Like airway-tube holder 100, the pressure applied against an airway tube by ment arm 942/thumb screw 930 can be released in either of two ways. Either by ”un-screwing” it, or by actuating quick-release mechanism 1094.
Referring again to FIGs. 9A, 93, and 9C, arms 1084, arms 1088, and plate member 1090 collectively function as quick-release mechanism 1094 for ling threads 932 of thumb screw 930 from partial female threads 1086. The quick-release ism is ed by lifting plate member 1090. This is in contrast to the illustrative embodiment, wherein plate member 690 is pushed to actuate the quick release function.
Lifting plate member 1090 causes l female threads 1086 to move outwardly. This disengages l female threads 1086 from threads 932 of thumb screw 930. Once the female threads are disengaged, thumb screw 930 can be slid away from the formerly immobilized airway tube.
Like airway-tube holder 100, the female thread does not fully nd the male threads 932 of the thumb screw. As for airway-tube holder 100, the arc length of female threads 1086 must be less than 180 degrees, and preferably less than 90 s to ensure that the female threads fully disengage from the male threads.
Further Alternative Embodiments ] Although features such as canted strap-holding slots 116, embossed ikons 120, 692, and ribs 548 were disclosed in conjunction with airway-tube holder 100, it is to be understood that such es can be used in conjunction with airway-tube holder 900. Likewise, the syringe grip disclosed in conjunction with -tube holder 900 can be used in conjunction with airway-tube holder 100.
In some further alternative embodiments of an airway-tube holder, rather than including a separate engagement arm 142/942, the clamping head (i.e., clamping head 144/944) from the ment arm can simply be coupled to the end of thumb screw 130/930. In such embodiment, the clamping head must be free to rotate independently of the thumb screw. This ensures that regardless of the rotational position of the thumb screw, the clamping head can be rotated as necessary so that its curved clamping surface has the proper orientation with respect to an airway tube. Although such embodiments are mechanically marginally simpler than the illustrative or first alternative embodiment, they are less operationally elegant and may require that the aforementioned adjustment be made by a caregiver.
In yet some further embodiments similar to those mentioned directly above, the clamping head can be weighted so that regardless of the rotational ation of thumb 0, the clamping head always assumes the correct attitude with respect to the airway tube. For example, with reference to , the ”bottom” of clamping head 144 (the portion closest to lower partial ter 106 of face plate 102) would be ed, such as with an internally placed piece of dense metal or other dense material.
It is to be understood that the sure describes a few embodiments and that many variations of the invention can easily be devised by those d in the art after reading this disclosure and that the scope of the present invention is to be determined by the following claims.

Claims (23)

What is claimed is:
1. An airway-tube holder for lizing an airway tube, the airway-tube holder having a screw, an engagement arm and a face plate ured to fit over a patient's oral cavity, the engagement arm having one degree of freedom, which is linear, the engagement arm having a clamping head disposed at a first end thereof, the face plate having a tubereceiving surface and a holding block, wherein the screw and the engagement arm are coupled to one another and disposed in parallel relation, wherein a first end of the screw attaches to the clamping head, and wherein the holding block receives the screw and the engagement arm, and, when so received, the clamping head ly opposes the ceiving surface, the clamping head and the tube-receiving surface thus configured to immobilize the airway tube when in use, the screw having two degrees-of-freedom: linear and rotational, n the holding block comprises at least one partial female thread for engaging threads of the screw, and a first member that supports the partial female thread, wherein the holding block and the partial female thread are physically configured so that: (a) the screw slides past the partial female thread when the screw is subjected to a force having a first direction and being coaxial with a long axis of the screw, ing the linear degree-of-freedom; and (b) the screw is immobilized by the partial female thread when subjected to a force having a direction opposite to the first direction, ing the rotational degree-offreedom , and wherein the first member has a configuration and location that results in generation of a counterforce that increases thread grip n the partial female threads and the s of the screw in response to a force that results from incremental tightening of the screw.
2. The airway-tube holder of claim 1 wherein the threads of the screw have an asymmetric thread profile.
3. The airway-tube holder of claim 1 or claim 2 wherein the location at which the first member is supported results in a al offset between an elastic-hinge point and a thread-engagement point.
4. The airway-tube holder of any one of claims 1 to 3 wherein the location at which the first member is supported results in a horizontal offset between an elastic-hinge point and a -engagement point.
5. The airway-tube holder of any one of claims 1 to 4 sing a plate member, wherein the plate member is coupled to the first member, the plate member and the first member collectively comprising a release mechanism that is physically configured so that when actuated by applying, to the plate member, a force having a second direction, the partial female thread disengages from the threads of the screw.
6. The airway-tube holder of claim 5 wherein the second direction is towards the face plate, such that the force is applied by pushing the plate member.
7. The airway-tube holder of claim 5 wherein the second direction is away from the face plate, such that the force is applied by g the plate .
8. The airway-tube holder of claim 5 or claim 6 comprising a physical stop, n the stop limits movement of the plate member.
9. The airway-tube holder as in any one of the preceding claims wherein the clamping head has an arcuate surface and at least two arcuate ribs disposed thereon to facilitate coupling to the airway tube.
10. The airway-tube holder of any one of the preceding claims wherein the engagement arm comprises a stem, wherein a first end of the stem couples to the screw at a first end thereof proximal to a screw head, and the ng head couples to the screw al to a second end thereof.
11. The airway-tube holder of claim 10 wherein the screw head further comprises a groove that es the first end of the stem.
12. The airway-tube holder of any one of the preceding claims wherein the engagement arm is disposed outward of the screw relative to the face plate.
13. The airway-tube holder of any one of the preceding claims comprising a wall extending orthogonal to a major surface of the face plate, n the wall forms a portion of the holding block and at least a portion of the tube-receiving e.
14. The airway-tube holder of any one of the preceding claims comprising: a left strap-retaining slot and a right strap-retaining slot, the strap-retaining slots receiving a strap that couples the face plate to a patient, wherein: the left strap-retaining slot is disposed proximal to a left edge of the face plate and the right strap-retaining slot is disposed proximal to a right edge of the face plate, and wherein the strap-retaining slots are canted with respect to a vertical orientation when the face plate is in use, an upper portion of the left strap-retaining slot extending further rd relative to a lower portion thereof and an upper portion of the right strapretaining slot extending further rightward relative to a lower portion thereof.
15. The airway-tube holder of claim 1, wherein the holding block further comprises: (a) a first wall having (i) a first circular g and (ii) a first groove therein; (b) a second wall spaced apart from and parallel to the first wall, the second wall having (i) a second circular opening and (ii) a second groove therein; (c) a first arm and a second arm, wherein the arms: (i) are spaced apart from and parallel to one r, (ii) are disposed between the first and second walls, and (iii) depend from the first wall proximal to a bottom thereof, wherein the at least one partial female thread is ed between and coupled to the first and second arm.
16. The airway-tube holder of claim 15 wherein the partial female thread is asymmetric.
17. The airway-tube holder of claim 15 or claim 16 n the threads of the screw extend through the first circular opening and the second circular opening.
18. The airway-tube holder of any one of claims 15-17 wherein the threads of the screw are asymmetric.
19. The airway-tube holder of any one of claims 15-18 comprising a plate member, wherein the plate member is coupled to the first and second arms, the plate member and the first and second arms collectively comprising a quick-release mechanism that is physically configured so that when actuated by applying a force to the plate member, the l female thread disengages from the threads of the screw.
20. The airway-tube holder of claim 19 wherein a portion of the plate member superposes the second wall and wherein the portion of the plate member and a top of the second wall is separated by a gap having a first distance.
21. The airway-tube holder of claim 20 wherein motion of the plate member, the first and second arms, and the partial female thread is limited to the first distance.
22. The airway-tube holder of any one of claims 15-21 wherein the engagement arm is received by the first groove and the second groove.
23. An airway-tube holder according to claim 1, ntially as herein described or ified with nce to the accompanying drawings.
NZ737207A 2015-05-21 2016-05-20 Airway-tube holder NZ737207B2 (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
US14/718,768 2015-05-21
US14/718,768 US10046130B2 (en) 2015-05-21 2015-05-21 Airway-tube holder
PCT/IB2016/052983 WO2016185446A1 (en) 2015-05-21 2016-05-20 Airway-tube holder

Publications (2)

Publication Number Publication Date
NZ737207A NZ737207A (en) 2021-10-29
NZ737207B2 true NZ737207B2 (en) 2022-02-01

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