The invention relates generally to a surgical glove and to a hand mould for making such a glove. More specifically, the invention concerns a surgical glove which may be worn by a surgical doctor for an extended period of time while performing surgery.
In the course of a surgical procedure, a typical surgical glove is worn while the doctor is performing a surgery in a surgery room. A typical surgical glove can be worn from as little as 10 minutes to more than 15 hours to complete a procedure. In the course of a long surgery, many pairs of gloves are changed for cleanliness, leaving the surgical room for rest or food, good sterile practice, etc. Nevertheless the amount of time when the gloves are worn on the hands is long enough to cause hand fatigue. Such length of time puts a physical stress on the hands of the surgeon as the gloves are designed to be worn tight without slack or loose folds in order to maximize dexterity and sensitivity. Being elastic in nature, all surgical gloves exert a certain amount of pressure on the hands, the amount varying according to the type of materials, the elastic compression, the dimensions of the gloves or hands, and the shape of the gloves compared to the shape of the hands. The last factor is crucial as any shape that is not conforming to the shape of the hand will exert a certain amount of stress on the part of the hand that is out of conformance to the gloves. Hand fatigue is a major issue for surgeons due to the protracted length of some of these procedures. As such, methods of reducing hand fatigue, which is caused primarily by the fact that surgical gloves are worn tight to increase dexterity and sensitivity, are important factors in the design of surgical gloves.
GB-A-2148094 discloses a plastic glove made by dipping a hand-shaped form which comprises an index finger portion, a middle finger portion, a third finger portion and a little finger portion, each defining a curved line extending from the knuckle portion to the fingertip portion with an angle of curvature of from 35° to 90°. Preferably there is an included angle of less than 90° between a first tangent touching the curved line at the fingertip portion and a second tangent touching on the back side surface of the hand portion.
WO-A-98/14079 discloses an anatomically-accurate surgical glove manufactured from an elastomeric material, having an enlarged thumb ball portion and independently curved fingers.
Most surgical gloves today come in two shapes which are either with straight fingers or slightly curved fingers, the latter exemplified by WO-A-98/14079. This slightly curved shape is illustrated in
There is thus an unfulfilled need for a surgical glove that is able to address the hand fatigue problems faced by those who wear the surgical glove for a long period of time while working with surgical implements. The present invention was developed in consideration of this need.
In a first aspect, the invention provides a surgical glove hand mould comprising a set of digits, consisting of thumb and index, middle, ring and little fingers, wherein the digits are disposed in positions consistent with that of a human hand when holding a surgical implement.
In one embodiment, each of the digits includes at least one major bend.
In one specific embodiment, the digits of the mould are to copy the one major bend (Bend 1) of the proximal-middle joint for the index, middle, ring and little fingers. For the thumb, the one major bend (Bend 1) occurs at the metacarpal-proximal joint.
The location of Bend 1 of the fingers and thumb is defined as the point of the first bend measured from the base of the finger crouch as a percentage of the total length of the straightened finger from finger crouch to fingertip. An angle of bend (a) of the first bend of the fingers is defined as the acute angle formed by the intersection of a first line formed along the proximal bone and a second line formed along the middle bone. An angle of bend (a) of the first bend for the thumb is defined as the acute angle formed by the intersection of a first line formed along the metacarpal bone and a second line formed along the proximal bone.
In another embodiment, each of the digits includes two bends.
In one embodiment, the locations of Bend 1 are as per Table 1 herein.
In an embodiment, the digits of the mould are to copy the two bends of the proximal-middle joint and middle-distal bone joint for the index, middle, ring and little fingers. For the thumb, the first bend (Bend 1) occurs at the metacarpal-proximal joint and the second bend (Bend 2) occurs at the proximal-distal joint.
The location of Bend 2 of the fingers and thumb is defined as the point of the second bend measured from the base of the finger crouch as a percentage of the total length of the straightened finger from finger crouch to fingertip. An angle of bend (b) of the second bend of the fingers is defined as the acute angle formed by the intersection of a first line formed along the middle bone and a second line formed along the distal bone. An angle of bend (b) of the second bend is defined as the acute angle formed by the intersection of a first line formed along the proximal bone and a second line formed along the distal bone.
In one embodiment, the locations of Bend 1 and Bend 2 are as per Table 2 herein.
In a further embodiment, the thumb and index finger are relatively disposed to define a gap between them of approximately 1 cm.
In a second aspect, the invention provides a surgical glove formed using the mould according to the first aspect.
In an embodiment, each of the digits of the surgical glove includes at least one major bend. A first bend of the fingers is located at a proximal-middle joint. A first bend of the thumb is located at a metacarpal-proximal joint.
In another embodiment, each of the digits of the surgical glove includes two bends. A first bend of the fingers is located at a proximal-middle joint and the second bend of the fingers is located at a middle-distal joint. A first bend of the thumb is located at a metacarpal-proximal joint and the second bend of the thumb is located at a proximal-distal joint.
The glove mould or former may be made of ceramic, porcelain, aluminium, cast metal, polymers, or polymer-based material. The glove is formed by dipping the mould into a bath of liquid latex, which is then dried and vulcanized by heating to a temperature sufficient to crosslink the latex molecules. The gloves are stripped from the mould by hand or machine, individually in a two-dimensional movement.
The surgical glove may be made of any of natural latex, polyurethane, synthetic latex, polyisoprene latex, chloroprene latex, acrylonitrile butadiene based latex, and blends or combinations of these latex, PVC, SEBS, SIS and variants or combinations of these materials with any other latex(s) mentioned above.
The present invention seeks to provide a solution to the hand fatigue problems by introducing a particular and one or more distinctive bends in the fingers of the glove. Generally, the strain on a surgeon's hands is caused by the fact that the surgeon's hands are not posed in a way which resembles the pose of the hands when in rested position. In most cases, the surgeon will be holding a tool of some sort and so will have his hands almost closed. To overcome the tendency of the glove to return to its natural shape, one which approximates the shape of the hand when in rested position that the glove was produced with, the surgeon must exert continual force on the glove to grasp the tool. The present invention overcomes this limitation by creating a mould that, when used to make gloves, creates stress and slack in such a way that the natural shape of the glove when worn will approximate the pose of the surgeon's hands while manipulating a surgical implement.
The present invention thus reduces tension in the glove by using dimensional proportions that match closely the hand position most commonly occupied by a surgeon while retaining the tightness which provides improved sensitivity and dexterity. Unlike the above prior art that provides a gentle curve to the digits of the glove, the present invention is based on the idea of specific articulation required during the process of surgery including positioning of one or more bends in the former used to produce the gloves.
The present invention is illustrated, though not limited, by the following description of embodiments that are given by way of example only in conjunction with the accompanying drawings, in which:
If one is to wear a glove with fingers straight up from the palm, and the hand is to be folded into a fist, the biggest change in shape will be the fingers, followed a slight deformation of the back of hand. In this instance, if the hand is to be folded into a fist and held on in that position for a certain period of time, the fingers will start to tire and feel stressed to continue being folded into a fist due to the stress and pressure of the glove to unfold back to a straight finger pose.
In order to reduce this stress, the material of the glove can be made softer to reduce the elastic stress being exerted when deformed/stretched. However, there is a limit to this as a material that is too elastic will not function as a skin tight glove, easily stretching and will be unable to return to shape quickly.
Recognizing that given any material, a substantial amount of finger stress is actually coming from the amount of deformation, hence the elastic stress to return to shape, the present invention proposes to make a glove that conforms to the disposition of the hand of the surgeon most of the time when he is actually wearing the glove and at work on a surgical procedure.
The surgeon's hands can be in several poses: hands down by his side (very seldom), hands lifted to waist length with hands forward (very often) and using this same pose with the hands gripping something, be it a scalpel, tool, etc. (most common).
The invention is thus to address this position of the hands that is very often the position of the surgeon's hands when in surgery.
Most surgical gloves commonly available to the public come in the shape of slightly curved fingers glove as illustrated by
The invention is to make a glove that is shaped like a hand that is already in a casual folded disposition, as shown in
An embodiment of the invention as illustrated by
A typical range of angles of the fingers in the various positions are as follows, with
The angles vary depending on the ratio of the finger bones and also according to gender.
The invention takes into account the ratio of lengths of the fingers and the angles to produce a shape that is as close to the shape of the hand at those positions.
If we observe our own hands, most of the time our fingers are bent at two to three positions. Starting from the metacarpal, the first bend is at the metacarpal-proximal joint. The second bend is at the proximal-middle joint, and the third bend is at the middle-distal digit joint. The two major bends occur at the proximal-middle joint and the middle-distal joint.
The thumb does not have a middle bone. For the thumb, the two major bends occur at the metacarpal-proximal joint and the proximal-distal joint.
The locations of the bends are related and relative to the finger lengths. Typically surgical gloves are made to sizes of 5, 5.5, 6, 6.5, 7, 7.5, 8, 8.5, 9, 9.5 and 10. There are many finger lengths that can be designed and made without the need for compliance to any standards, international, regional or national. The only criterion is to attempt to match the general demographic anatomical size, with certain regions of the world preferring shorter fingers in a glove and others preferring generally longer fingers in a glove. This also depends on the size of the glove as described above.
The only parameter to which any international, regional or national standards apply is the width of the palm that is to match the sizes. The relevant standards are ASTM 3577, EN 455 and ISO 11232. These sizes again do not have any fixed standard finger lengths.
The first embodiment of the invention resides in a mould that has one major bend (Bend 1) in the digits as illustrated in
In order to be suitable for any design of finger lengths, regardless of size, the percentages/ratios and angles rather than absolute dimensions are specified in Table 1.
The angle of bend (a) of the first bend for the index, middle, ring and little fingers is defined as the acute angle formed by the intersection of a first line formed along the proximal bone and a second line formed along the middle bone.
The angle of bend (a) of the first bend for the thumb is defined as the acute angle formed by the intersection of a first line formed along the metacarpal bone and a second line formed along the proximal bone.
The second embodiment of the invention resides in a mould that has two major bends in the digits as illustrated in
In this second embodiment, the aggregate of the two bends from the metacarpal line will be the defining angle as measured as angle of bend (c). See Table 2.
The angle of bend (b) of the second bend for the index, middle, ring and little fingers is defined as the acute angle formed by the intersection of a first line formed along the middle bone and a second line formed along the distal bone. The angle of bend (c) is the combined aggregate angles of bend (a) and bend (b).
The angle of bend (b) of the second bend for the thumb is defined as the acute angle formed by the intersection of a first line formed along the proximal bone and a second line formed along the distal bone. The angle of bend (c) is the combined aggregate angles of bend (a) and bend (b).
The invention may also be embodied in many ways other than those specifically described herein, without departing from the scope thereof.
Number | Date | Country | Kind |
---|---|---|---|
PI 2012005261 | Dec 2012 | MY | national |