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WO1999053786A1 - Laminated insole insert for footwear - Google Patents

Laminated insole insert for footwear Download PDF

Info

Publication number
WO1999053786A1
WO1999053786A1 PCT/US1999/008521 US9908521W WO9953786A1 WO 1999053786 A1 WO1999053786 A1 WO 1999053786A1 US 9908521 W US9908521 W US 9908521W WO 9953786 A1 WO9953786 A1 WO 9953786A1
Authority
WO
WIPO (PCT)
Prior art keywords
user
metatarsal
heel
foot
insole insert
Prior art date
Application number
PCT/US1999/008521
Other languages
French (fr)
Inventor
Jeffrey S. Brooks
James G. Brown
Original Assignee
Payless Shoesource, Inc.
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
Application filed by Payless Shoesource, Inc. filed Critical Payless Shoesource, Inc.
Priority to AU37507/99A priority Critical patent/AU3750799A/en
Publication of WO1999053786A1 publication Critical patent/WO1999053786A1/en

Links

Classifications

    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B7/00Footwear with health or hygienic arrangements
    • A43B7/14Footwear with health or hygienic arrangements with foot-supporting parts
    • A43B7/1405Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form
    • A43B7/1415Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form characterised by the location under the foot
    • A43B7/142Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form characterised by the location under the foot situated under the medial arch, i.e. under the navicular or cuneiform bones
    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B1/00Footwear characterised by the material
    • A43B1/0045Footwear characterised by the material made at least partially of deodorant means
    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B13/00Soles; Sole-and-heel integral units
    • A43B13/38Built-in insoles joined to uppers during the manufacturing process, e.g. structural insoles; Insoles glued to shoes during the manufacturing process
    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B17/00Insoles for insertion, e.g. footbeds or inlays, for attachment to the shoe after the upper has been joined
    • A43B17/02Insoles for insertion, e.g. footbeds or inlays, for attachment to the shoe after the upper has been joined wedge-like or resilient
    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B17/00Insoles for insertion, e.g. footbeds or inlays, for attachment to the shoe after the upper has been joined
    • A43B17/14Insoles for insertion, e.g. footbeds or inlays, for attachment to the shoe after the upper has been joined made of sponge, rubber, or plastic materials
    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B7/00Footwear with health or hygienic arrangements
    • A43B7/14Footwear with health or hygienic arrangements with foot-supporting parts
    • A43B7/1405Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form
    • A43B7/1415Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form characterised by the location under the foot
    • A43B7/144Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form characterised by the location under the foot situated under the heel, i.e. the calcaneus bone
    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B7/00Footwear with health or hygienic arrangements
    • A43B7/14Footwear with health or hygienic arrangements with foot-supporting parts
    • A43B7/1405Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form
    • A43B7/1415Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form characterised by the location under the foot
    • A43B7/1445Footwear with health or hygienic arrangements with foot-supporting parts with pads or holes on one or more locations, or having an anatomical or curved form characterised by the location under the foot situated under the midfoot, i.e. the second, third or fourth metatarsal
    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B7/00Footwear with health or hygienic arrangements
    • A43B7/14Footwear with health or hygienic arrangements with foot-supporting parts
    • A43B7/28Adapting the inner sole or the side of the upper of the shoe to the sole of the foot

Definitions

  • This invention relates generally to footwear and, more specifically without
  • a contoured insole structure may be provided in children's shoes to
  • the heel is generally the first part of the foot to strike the ground, with the foot then
  • the bone structural alignment should be firmly supported
  • support include the first, second, third, fourth and fifth metatarsal heads, indicated
  • proximal phalanges P1-P5 indicated at Jl through J5 in Fig. 1.
  • Plantflex in order for the toe to function appropriately.
  • the progressive phases of gait are heel strike, when the heel hits the
  • the second and third metatarsals be firmly supported, and that the first
  • metatarsal head plantarflex moves downward relative the second and third
  • the toes also should generally be firmly supported during toe-off
  • weight-generated forces may cause these early weight-bearing feet to permanently
  • organs would normally realize greatest efficiency (including an optimal ratio of
  • supination and pronation is one in which the subtalar joint is approximately forty-
  • leg and calcaneus are perpendicular to the weight bearing surface
  • knee joint ankle joint and forefoot, including the plane of the metatarsal heads,
  • a fully developed human foot can generally be described as having one of
  • the heel area of the foot is typically slight, while the amount of adduction in a high-
  • arch foot is generally much greater. Further, the movement of a normal or flat foot
  • Plant fascial tears or “plantar fasciitis”, which generally arise from
  • tibial sesamoiditis great toe joint, sometimes referred to as "tibial sesamoiditis", generally
  • shin splint generally arising from improper articulation of
  • human foot may start to breakdown as a result of degenerative disease by the age of
  • An improved insole insert comprising a body, a metatarsal cutout, and a heel
  • the body has an upper member constructed of flexible material having a
  • the heel portion includes a
  • the arch portion extends forwardly from the medial portion along the medial side
  • the medial portion and the arch portion which are configured to be
  • the body also generally includes a lower member, preferably having a
  • substantially uniform thickness that is connected to the upper member and has a
  • a metatarsal cutout in the lower member is dimensioned and configured to be
  • metatarsal cutout has a longitudinal side spaced operatively between the user's first
  • a heel cutout in the lower member is generally operatively centered beneath
  • the upper member, the lower member, and the metatarsal cutout are identical to the upper member, the lower member, and the metatarsal cutout.
  • metatarsal member having a transversely oriented front edge
  • the arch member is secured to the underside of an arch portion of the upper
  • the arch member is configured to operatively provide support for at least
  • the arch member has a boundary
  • intermediate segment is configured to operatively pass approximately
  • medial segment is configured to operatively pass approximately beneath the first
  • metatarsal neck of the user's foot and the aft medial segment is configured to
  • contoured portions thereof are configured to cooperatively redistribute
  • Fig. 1 is a schematic illustration, showing a top plan view of an insole of a left
  • Fig. 2 is a top perspective view of a laminated insole insert for a user's left foot
  • Fig. 3 is a bottom plan view of the laminated insole insert for a user's left foot
  • Fig. 4 is a top perspective view of the laminated insole insert, similar to Fig. 2
  • Fig. 5 is a vertical cross-sectional view of the laminated insole insert for a
  • Fig. 6 is a bottom plan view of a first modified embodiment of the laminated
  • Fig. 7 is a schematic side elevational view of the first modified embodiment of
  • Fig. 8 is a vertical cross-sectional view of the first modified embodiment of the
  • Fig. 9 is a top perspective view of a second modified embodiment of the
  • Fig. 10 is a reduced top plan view of the second modified embodiment of the
  • laminated insole insert shown in relation to a user's left foot.
  • Fig. 11 is an enlarged, vertical cross-sectional view of the second modified
  • Fig. 12 is a further enlarged, vertical cross-sectional view of the second
  • Fig. 9 is a top perspective view of a second modified embodiment of the
  • Fig. 7 is an enlarged top plan view of the insole insert having perforation-
  • Fig. 7a - 7i are enlarged cross-sectional views of the insole insert having
  • the reference numeral 1 generally refers to a laminated insole insert in
  • insole insert 1 generally comprises a body member 11 having an upper surface 13 for
  • the body member 11 generally includes one or more layers or components as
  • laminated insole insert 1 may vary as is customary, depending upon the size of
  • the upper surface 13 of the body member 11 may be overlaid with a
  • an antibacterial and/or antimicrobial agent may also be impregnated with an antibacterial and/or antimicrobial agent.
  • molded or otherwise formed is preferably a pliable substance that provides the desired
  • the material selected is selected from:
  • the upper member 25 generally has a uniform thickness, a preferred material
  • one of laminated insole inserts 1 has a thickness of approximately 4 mm.
  • regions of the upper member 25 are defined
  • toe edge 27 As a toe edge 27, a heel edge 33, a medial side edge 35, and a lateral side edge 37
  • the upper member 25 includes a heel
  • portion 43 having a lateral portion 45 and a medial portion 47, and an arch portion 53.
  • the body member 11 also includes a lower member 55, generally constructed of the
  • the lower member 55 may have the same thickness as the upper member
  • the lower member 55 may be thicker or thinner than the upper
  • the lower member 25 For example, in one of the exemplary specimens, the lower member 25
  • the body member 11 preferably has a Type C (commonly referred to as
  • the body member 11 may have a Type C durometer hardness (ASTM D 2240-97) of
  • the body member 11 may
  • the body member 11 should be sufficiently
  • the lower member 55 has a front edge 57, a heel edge 63, a medial side edge
  • lateral side edge 67 of the lower member 55 are profiled and dimensioned to fit just
  • medial side edge 65 and the lateral side edge 67 of the lower member 55 are also
  • the lateral portion 45 of the upper member 25 extends forwardly along the
  • the lateral portion 45 extends transversely outwardly from the lower
  • the medial portion 47 of the heel portion 43 extends forwardly along
  • medial portion 47 extends transversely outwardly from the lower member 55
  • medial heel flap 85 that is displaced upwardly against a medial side 87 of the shoe 23
  • the arch portion 53 extends forwardly along the medial side edge 35
  • arch portion 53 extends transversely outwardly from the lower
  • the arch portion 53 is approximately 2.0 cm, or approximately twenty-five percent of
  • end 73 of the lateral portion 45 of the heel portion 43 is spaced approximately 9.0
  • portion 43 extends forwardly to approximately 7.0 centimeters in front of the rearmost
  • part 75 of the heel or approximately thirty percent of the overall length of the upper
  • medial portion 47 of the heel portion 43 may be any medial portion 47 of the heel portion 43.
  • the medial portion 47 may be separated from
  • the front edge 57 of the lower member 55 is dimensioned and configured to
  • the lower member 55 also includes a metatarsal cutout
  • the lower member 55 has a heel cutout 113 operatively spaced
  • specimens has a generally circular or ovular shape, with an overall fore-and-aft
  • the heel portion 43 and the arch portion 53 are configured and
  • arch portion 53 in conjunction with the heel cutout 113, are configured to redistribute
  • the metatarsal cutout 103 is configured to permit the user's first metatarsal-
  • cutout 103 which is generally spaced such that the user's first metatarsal phalangeal
  • joint Jl is spaced approximately centrally there over, is configured to have sufficient
  • metatarsal cutout 103 permits the first metatarsal
  • metatarsal cutout 103 may be approximately
  • the arch portion 53 in conjunction with the metatarsal cutout 103, is
  • cutout 103 are configured such that cooperative interaction therebetween reduces
  • arch portion 53 is configured to promote more
  • the body member 11 the metatarsal
  • cutout 103, the heel portion 43, and the arch portion 53 are configured such that
  • the F-scan system uses paper-
  • the F-scan insole devices are flexible and
  • the F-scan insoles are attached directly to the bottom of a sock
  • F-scan system as they sequentially occur during a normal gait cycle and/or during
  • F-scan computerized gait analysis system In regard to the present invention, F-scan computerized gait analysis system
  • the laminated insole insert 1 in addition to cooperatively redistributing weight-
  • body member 11 of the laminated insole insert 1 provides cushioning for the shocks
  • the first metatarsal phalangeal joint stabilizes as it must before the user's
  • M1-M5 also serves to redistribute weight-generated forces applied there against
  • the laminated insole insert 1 allows the user's first metatarsal
  • insole insert 1 appropriately provides all of the necessary supporting and stabilizing
  • the laminated insole insert 1 is adapted to support
  • metatarsal phalangeal joint and associated sesamoid apparatus to function properly.
  • footwear made for mnning may
  • Figs. 6 through 8 the present invention is shown in Figs. 6 through 8 and is generally designated by
  • the first modified embodiment 119 adapted for insertion in a wearer's shoe
  • 121 generally comprises a body member 123 including an upper member 125 having
  • a toe edge 127 a heel edge 133, a medial side edge 135, and a lateral side edge 137.
  • the upper member 125 includes a heel portion 143, having a lateral portion 145 and a
  • the body member 123 also includes a
  • the lower member 155 has a front edge 157, a heel edge 163, a medial side edge 165,
  • the lateral portion 145 of the upper member 125 extends forwardly along the
  • the lateral portion 145 extends transversely outwardly from the lower member
  • a lateral heel flap 177 that is displaced upwardly against a lateral side 183 of the shoe
  • the medial portion 147 of the upper member 125 extends forwardly
  • medial portion 147 extends transversely outwardly from the lower member 155
  • the arch portion 153 extends forwardly along the medial side edge
  • the front edge 157 of the lower member 155 is dimensioned and configured to
  • the lower member 155 also includes a metatarsal cutout 203 having a
  • longitudinal side 205 operatively spaced between a user's first and second metatarsal
  • sesamoids there below to appropriately plantar flex between midstance and toe-off
  • the lower member 155 has a heel cutout 213
  • the metatarsal cutout 203 is configured to permit the user's first metatarsal
  • cutout 203 which is generally spaced such that the user's first metatarsal phalangeal
  • joint Jl is spaced approximately centrally there over, is configured to have sufficient
  • the body member 123 of the first modified embodiment 119 also includes a
  • metatarsal member 215, generally constructed of the same type of material as the
  • lower member 155 preferably the "POLIYOU” material, that is laminated or
  • 30 metatarsal member 215 may have the same thickness as the upper member 125, the
  • member 215 has a front edge 217 that is approximately transversely aligned with the
  • the metatarsal member 215 is
  • metatarsal member 215 is dimensioned and
  • one of the exemplary specimens has an overall fore-and-aft dimension of
  • Figs. 9 through 12 is shown in Figs. 9 through 12 and is generally designated
  • embodiment 219 are substantially similar to those of the previously described
  • the second modified embodiment 219 adapted for insertion in a wearer's shoe
  • a body member 225 having a toe edge 227, a heel edge 233,
  • the body member 225 includes a medial side edge 235, and a lateral side edge 237.
  • the body member 225 includes a
  • heel portion 243 having a lateral portion 245 and a medial portion 247, and an arch
  • the second modified embodiment 219 also includes an arch member 255
  • the body member 225 that is laminated or otherwise secured to, the body member 225.
  • the lateral portion 245 of the body member 225 extends forwardly along the
  • lateral portion 245 extends transversely outwardly beginning
  • the medial portion 247 extends transversely outwardly beginning approximately at
  • the arch portion 253 extends forwardly along the medial side edge
  • arch portion 253 extends transversely outwardly beginning at the
  • the arch member 255 is adapted to underlie and support the second and third
  • member 255 essentially defines a boundary, designated by the numeral 303 in Figs.
  • the fore medial segment 305 of the boundary 303 is offset
  • the fore medial segment 305 passes
  • intermediate segment 307 passes approximately or directly beneath the necks of the
  • FIG. 11 shows the second modified
  • the body member 225 of softer material preferably has a Type C (commonly
  • hardness may be greater or lesser as desired. For example, if the footwear is
  • the body member 225 may have a Type C durometer hardness
  • the body member 225 may have a hardness of about 60. In short, the body member
  • the arch member 225 of harder material preferably
  • Type C durometer hardness (ASTM D 2240-97) of 50-85, and preferably
  • the body 42 preferably has a hardness of about 75.
  • body member 225 and the arch member 255 may be bonded to one another in any
  • the arch member 255 can be formed of any suitable material, such as
  • 255 may be constructed of different colored materials to thereby enhance the
  • the softer material of the body member 225 compresses relatively easily
  • the areas of the body member 225 are
  • areas of the arch member 255 are configured to, among other things, more
  • the arch member 255 firmly supports the osseous alignment
  • the arch member 255 provides necessary support for the second and third
  • body member 225 permits the first metatarsal neck Nl and head Ml to plantarflex
  • embodiment 219 extends generally between the third and fourth metatarsal necks
  • N3, N4 continues rearwardly approximately beneath the juncture between the
  • the body member 225 located distally from the arch member 255, interacts
  • member 255 provides support for the metatarsal necks, proximal phalanges and
  • metatarsal phalangeal joints associated with the second and third metatarsal heads associated with the second and third metatarsal heads.
  • the structural design of the second modified embodiment 219 provides

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  • Health & Medical Sciences (AREA)
  • Epidemiology (AREA)
  • General Health & Medical Sciences (AREA)
  • Public Health (AREA)
  • Footwear And Its Accessory, Manufacturing Method And Apparatuses (AREA)

Abstract

An insole insert (1) comprises a body (11) of flexible resilient material with an upper member (25) having lateral (45) and medial (47) heel portions, an arch portion (53), and a lower member (55), each member having a uniform thickness, a metatarsal cutout (103), and a heel cutout (103). The heel (43) and arch portions (53) are displaceable upwardly along the sides of the user's footwear. The lower member (55) has a front edge (57) spaced rearwardly from the user's second and third metatarsal phalangeal joints. The metatarsal cutout (103) is centered beneath the user's first metatarsal joint. The heel cutout (113) is centered beneath the user's heel. One embodiment includes a metatarsal member (215) having a front edge approximately transversely aligned with the transverse side of the metatarsal cutout (103), secured to the lower member (55).

Description

LAMINATED INSOLE INSERT FOR FOOTWEAR
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates generally to footwear and, more specifically without
limitation, to an insole insert for footwear.
2. Description of the Related Art
Although children are usually born with normal arches, as a child begins to
walk and body weight is applied to his feet as they bear against a supporting surface,
his foot structure necessarily reacts by tending to flatten out under the weight-
generated forces applied to the soles of his feet. If the child were walking only on
natural supporting surfaces, e.g. , the ground, the normal age for the child to be able
to stand without the need of external support for his feet is generally considered to
be approximately eight years of age. For purposes of improved appearance,
convenience, endurance, etc., however, man-made products are generally applied to
those supporting surfaces. Unfortunately, such "improved" surfaces tend to be
detrimental to the human musculoskeletal structures, especially during the
developmental stages when the child's foot structure is "soft" and incompletely
formed. Due to such negative environmental influences on the human foot structure, shoes which provide proper support and shock attenuation should be worn
for protection and prevention of structural injury.
As disclosed in U.S. Patent No. 4,272,899, issued June 16, 1981 to Jeffrey
S. Brooks, the disclosures and teachings of which are incorporated herein by
reference, a contoured insole structure may be provided in children's shoes to
reduce abnormal stress from the heel to the metatarsals by properly supporting and
stabilizing the feet during development thereof. By so doing, the associated stresses
placed upon the medial column of the foot is also reduced, distributing the body
weight more evenly on the sole of the foot.
More specifically, when walking or running, the lateral (outside) portion of
the heel is generally the first part of the foot to strike the ground, with the foot then
pivoting on the heel to bring the lateral part of the forefoot into a position whereat it
bears against an underlying surface. At that point,the foot resides in a supinated
(inclined upwardly from the lateral to the medial side of the foot). The foot then
pronates until all of the metatarsal heads are in the horizontal plane (flat to the
supporting surface). The bone structural alignment should be firmly supported
when the foot assumes such neutral position in order to prevent the ligaments,
muscles and tendons of the foot from becoming over-stressed.
Various skeletal characteristics of the feet that are pertinent to proper foot
support include the first, second, third, fourth and fifth metatarsal heads, indicated
in phantom at Ml through M5 in Fig. 1 ; first, second, third, fourth and fifth
metatarsal necks associated with the respective metatarsal heads M1-M5, indicated
2 in phantom at Nl through N5; first, second, third, fourth and fifth proximal
phalanges spaced distally from the respective metatarsal heads M1-M5, indicated in
phantom at PI through P5; and first, second, third, fourth and fifth metatarsal
phalangeal joints spaced between the respective metatarsal heads M1-M5 and
proximal phalanges P1-P5, indicated at Jl through J5 in Fig. 1. Further, various
muscles and tendons characteristically interact to stabilize the foot during the
sequence of progressive movements normally experienced in a walking or ranning
gait in preparation for movement from the neutral position to a propulsive phase of
the gait cycle, sometimes referred to as "toe-off" or "push-off .
Flexion of the first metatarsal phalangeal joint (i.e., the great toe joint) is
normally approximately fifteen degrees to the associated metatarsal in a dorsiflex
position when standing, and increases to between sixty-five and ninety degrees,
depending on the available motion and the activity required by the joint just prior to
lifting off the underlying supporting surface. The relationship among the foot bones is
such that the first metatarsal phalangeal joint and the two small bones there beneath,
the tibial sesamoid and the fϊbular sesamoid, should be displaced downwardly
("plantarflex") in order for the toe to function appropriately.
Thus, the progressive phases of gait are heel strike, when the heel hits the
ground; midstance, when stability of the arch is an essential necessity; and propulsive
phase, as the heel lifts off the ground and the body weight shifts onto the ball of the
foot. During the transition from the neutral position through toe-off, it is preferable that the second and third metatarsals be firmly supported, and that the first
metatarsal head plantarflex (move downward) relative the second and third
metatarsal heads. The toes also should generally be firmly supported during toe-off
so that they remain straight, and thus stronger, promoting a "pillar effect" by the
phalanges.
To provide additional insight into some of the mechanisms of the human feet,
it is known that the lower limbs of the human embryo begin to rotate internally
ninety degrees from an external position at the pelvic girdle at approximately the
eighth week of fetal development. At the twelfth week of development, the feet
begin to dorsiflex, and around the sixteenth week of development, the completely
inverted feet begin to evert, all of which are part of the complex preparation of the
lower extremity for upright, bi-pedal weight-bearing posture and locomotion. A
child's feet and legs have sometimes been described as a loose bag of bones and
cartilage floating in a mass of soft tissue until about age six. As a result, foot
posture is a rapidly changing proposition for children under the age of six years.
The true structure of a child's foot is not developed until approximately seven or
eight years of age when development of the sustentaculum tali is generally complete.
Further, eighty to ninety percent of the child's adult foot size is developed by the
age of ten, with complete development occurring by approximately age 14-16 years
in human females and age 15-17 years in human males.
When infants begin to bear weight, their feet begin to pronate excessively
because their feet are not yet ready, without deformation, to be placed on an
4 unnatural surface, such as a hard flat surface. As a result, if uncorrected, repeated
weight-generated forces may cause these early weight-bearing feet to permanently
deform (excessive pronation). Thus, such early-age, weight-bearing feet should
preferably be maintained in proper postural alignment by providing a more natural
environment therefor, such as a better supporting interface between the feet and the
underlying supporting surfaces, thereby allowing the feet to develop as normally as
possible during their postnatal development.
Therefore, as soon as the child begins to bear weight on his feet, usually
around six to seven months of age, treatment to neutralize excessive pronation
should be instituted. The user's feet should be placed in their individually most
efficient position to function properly and to reduce excessive strain not only on the
feet but also on the lower body structure supported by the feet. In an ideal foot
posture situation for minimal stress, the position in which the feet as weight-bearing
organs would normally realize greatest efficiency (including an optimal ratio of
supination and pronation) is one in which the subtalar joint is approximately forty-
two degrees from the transverse plane, approximately sixteen degrees from the
saggital plane, and approximately forty-eight degrees from the frontal plane,
sometimes referred to as the neutral position hereinbefore mentioned. In the neutral
position, the leg and calcaneus are perpendicular to the weight bearing surface, and
the knee joint, ankle joint and forefoot, including the plane of the metatarsal heads,
are substantially parallel to the subtalar joint and to the walking surface. A fully developed human foot can generally be described as having one of
three basic types: normal, low arch ("flat foot"), or high arch. From an anatomical
standpoint, normal and flat feet are capable of being functionally controlled by the
same basic shoe control mechanism, while a high-arch foot is structurally different
and may require a different supporting environment. For example, the amount of
adduction ("pigeon-toedness") of the front part of a normal or flat foot in relation to
the heel area of the foot is typically slight, while the amount of adduction in a high-
arch foot is generally much greater. Further, the movement of a normal or flat foot
during running is also substantially different from that of a high-arch foot. If proper
support and stabilization is not properly implemented during their early formative
development, fully developed feet may be more susceptible to, and be more prone to
suffer from, various maladies, including the following:
(a) tearing of the plantar fascia tissues which connect the heel to the
ball of the foot and support the arch of the foot, sometimes referred to as
"plantar fascial tears" or "plantar fasciitis", which generally arise from
stressful upward pulls on the calcaneus ("heel bone") and strain of the
intrinsic or interior foot muscles, and is generally realized as heel pain;
(b) excessive stress between adjacent metatarsals, sometimes referred
to as "metatarsal stress fractures", generally arising from improper support of
the talonavicular joint ("arch") and instability of the first ray ("great toe
joint"); (c) irritation of the tissue associated with a small bone beneath the
great toe joint, sometimes referred to as "tibial sesamoiditis", generally
arising from inappropriate support of the talonavicular joint and/or
inappropriate weight distribution between the various metatarsal phalangeal
joints;
(d) excessive bony growth on the top of the foot, sometimes referred
to as "saddle joint deformity", generally arising from improper movement of
the first metatarsal and realized in the form of degenerative arthritis;
(e) inflammation and/or separation of tissue from the tibia, sometimes
referred to as "shin splint", generally arising from improper articulation of
the talonavicular joint between the ankle bone and the key supporting bone of
the foot and generally realized as fatigue of the muscles in the front and back
of the leg; and
(f) bruising in the bottom center of the heel generally arising from
disproportionally greater weight-generated forces applied thereto.
Such maladies should be given due consideration, both in youth and in adults, as the
human foot may start to breakdown as a result of degenerative disease by the age of
thirty-five years.
In view of the foregoing, it should be obvious that certain parts of the feet are
generally subjected to higher stresses during standing, running and walking, and that
other parts of the feet require different degrees of support for maximum
biomechanical efficiency, particularly since high impact forces to the foot are
7 generally transferred to other skeletal structures, such as the shins, knees, and lower
back region.
Control of the user's foot must begin in the heel and proceed to the arch,
including providing stability of the forefoot in order for the foot to function properly
through the normal phases of gait. Various devices have been developed in attempts
to provide needed support and stabilization for a user's feet. A frequent problem
with most of such devices, however, is getting the devices to not only properly fit
the user's feet but, in the case of insole inserts, to also fit the user's shoes while
properly supporting and stabilizing the user's feet.
Thus, what is needed is a device, when placed into footwear, provides an
appropriate amount of support and shock attenuation for different regions of the foot
to thereby provide a proper environment that promotes a balanced foot position for
healthy postural and skeletal structural development thus allowing the parts of the
foot to function in a way which provides maximum efficiency, to prepare the body
for stresses normally subjected thereto, and to protect those parts of the foot which
are subjected to high impact forces.
SUMMARY OF THE INVENTION
An improved insole insert, comprising a body, a metatarsal cutout, and a heel
cutout. The body has an upper member constructed of flexible material having a
substantially uniform thickness, with a heel portion, an arch portion, a toe edge, a heel edge, a lateral side edge, and a medial side edge. The heel portion includes a
medial portion extending along the heel edge and the medial side edge, and a lateral
portion extending along the heel edge and the lateral side edge of the upper member.
The arch portion extends forwardly from the medial portion along the medial side
edge. The medial portion and the arch portion, which are configured to be
displaceable upwardly alongside the medial side of the user footwear, and the lateral
portion, which is configured to be displaceable upwardly alongside the lateral side of
the user footwear, operatively and cooperatively redistribute weight-generated forces
bearing against the sole of the user's foot such that greater weight-generated forces
that normally bear against certain regions of the sole of the user's foot are
substantially reduced and redistributed toward other regions of the user's foot
whereat normally smaller weight-generated forces usually bear against the user's
foot.
The body also generally includes a lower member, preferably having a
substantially uniform thickness, that is connected to the upper member and has a
front edge operatively spaced just rearwardly from at least the user's second and
third metatarsal phalangeal joints.
A metatarsal cutout in the lower member is dimensioned and configured to be
generally operatively centered beneath the user's first metatarsal joint. The
metatarsal cutout has a longitudinal side spaced operatively between the user's first
and second metatarsal phalangeal joints, and a transverse side, spaced operatively
just rearwardly from the user's first metatarsal phalangeal joint.
9 A heel cutout in the lower member is generally operatively centered beneath
the user's heel whereat the greatest weight-generated forces are normally applied.
The upper member, the lower member, and the metatarsal cutout are
dimensioned and configured to cooperatively allow the user's first metatarsal
phalangeal joint and his sesamoids there below to appropriately plantarflex between
the midstance and toe-off phases of the user's gait.
A first modified embodiment of the insole insert includes a metatarsal
member, having a substantially uniform thickness and connected to the lower
member, with the metatarsal member having a transversely oriented front edge
approximately transversely aligned with the transverse side of the metatarsal cutout.
A second modified embodiment of the insole insert comprises an upper
member, constructed of a first resilient material, and an arch member, constructed
of a second resilient material that is harder than the first resilient material, wherein
the arch member is secured to the underside of an arch portion of the upper
member. The arch member is configured to operatively provide support for at least
the second and third metatarsal necks of the user's foot and for the user's arch
throughout supported phases of the user's gait. The arch member has a boundary
with a fore medial segment, an intermediate segment and an aft medial segment,
wherein the intermediate segment is configured to operatively pass approximately
beneath at least the second and third metatarsal necks of the user's foot, the fore
medial segment is configured to operatively pass approximately beneath the first
metatarsal neck of the user's foot, and the aft medial segment is configured to
10 operatively extend generally between the user's third and fourth metatarsal necks,
continue rearwardly approximately beneath the juncture between the user's cuboid
bone and lateral cuniform bone, and curve gradually rearwardly and medially to the
medial side edge to pass approximately beneath the juncture between the user's
navicular bone and the forward end of the medial tuberosity of the user's foot.
PRINCIPAL OBJECTS AND ADVANTAGES OF THE INVENTION
The principal objects and advantages of the present invention include:
providing a device for insertion into existing footwear; providing such a device that is
tailored to the biomechanical operation of the wearer's foot; providing such a device
for properly supporting and cushioning various regions of the wearer's foot;
providing such a device that redistributes weight-generated forces applied to the sole
of the wearer's foot whereby the range of such forces is substantially reduced;
providing such a device wherein arch and heel portions thereof are configured to
cooperatively redistribute normally greater weight-generated forces bearing against
the bony central region of the heel outwardly toward the larger, more fleshly outer
regions of the heel to thereby substantially reduce the range of weight- generated
forces normally applied to the heel regions of a user's foot; providing such a device
wherein contoured portions thereof are configured to cooperatively redistribute
normally greater weight-generated forces bearing against the heel, arch, and forefoot
regions of a user's foot to other regions of the user's foot to which substantially
11 smaller weight-generated forces are normally applied; and generally providing such a
device that is efficient in operation, reliable in performance, and is particularly well
adapted for the proposed usage thereof.
Other objects and advantages of the present invention will become apparent
from the following description taken in conjunction with the accompanying drawings,
which constitute a part of this specification and wherein are set forth exemplary
embodiments of the present invention to illustrate various objects and features thereof.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is a schematic illustration, showing a top plan view of an insole of a left
shoe and illustrating the approximate position of the metatarsal and related bone
structure of a user's left foot in relation thereto.
Fig. 2 is a top perspective view of a laminated insole insert for a user's left foot,
in accordance with the present invention.
Fig. 3 is a bottom plan view of the laminated insole insert for a user's left foot,
showing various features thereof.
Fig. 4 is a top perspective view of the laminated insole insert, similar to Fig. 2
but illustrating upward displacement of heel and arch portions thereof when placed in
a shoe.
Fig. 5 is a vertical cross-sectional view of the laminated insole insert for a
user's right foot, taken along line 5-5 of Fig. 4 and showing a shoe in phantom.
12 Fig. 6 is a bottom plan view of a first modified embodiment of the laminated
insole insert for a user's left foot, showing various features thereof in accordance with
the present invention.
Fig. 7 is a schematic side elevational view of the first modified embodiment of
the laminated insole insert, showing a user's left foot in relation thereto, with upward
displacement of an arch portion thereof when placed in a shoe.
Fig. 8 is a vertical cross-sectional view of the first modified embodiment of the
laminated insole insert for a user's left foot, showing a shoe in phantom, according to
the present invention.
Fig. 9 is a top perspective view of a second modified embodiment of the
laminated insole insert for a user's left foot, in accordance with the present invention.
Fig. 10 is a reduced top plan view of the second modified embodiment of the
laminated insole insert, shown in relation to a user's left foot.
Fig. 11 is an enlarged, vertical cross-sectional view of the second modified
embodiment of the laminated insole insert showing a right shoe in phantom.
Fig. 12 is a further enlarged, vertical cross-sectional view of the second
modified embodiment of the laminated insole insert, taken along line 12-12 of Fig. 9,
according to the present invention.
Fig. 9 is a top perspective view of a second modified embodiment of the
laminated insole insert for a user's left foot, in accordance with the present invention.
Fig. 7 is an enlarged top plan view of the insole insert having perforation-
modified resiliency.
13 Fig. 7a - 7i are enlarged cross-sectional views of the insole insert having
perforation-modified resiliency, taken respectively along lines a-a through i-i of Fig. 7,
according to the present invention.
DETAILED DESCRIPTION OF THE INVENTION
As required, detailed embodiments of the present invention are disclosed
herein; however, it is to be understood that the disclosed embodiments are merely
exemplary of the invention, which may be embodied in various forms. Therefore,
specific structural and functional details disclosed herein are not to be interpreted as
limiting, but merely as a basis for the claims and as a representative basis for teaching
one skilled in the art to variously employ the present invention in virtually any
appropriately detailed structure.
The reference numeral 1 generally refers to a laminated insole insert in
accordance with the present invention, as shown in Figs. 2 through 5. The laminated
insole insert 1 generally comprises a body member 11 having an upper surface 13 for
comfortable stable support of a wearer's foot as hereinafter described, and a lower
surface 15 for bearing against the insole 17 of a wearer's shoe 23.
The body member 11 generally includes one or more layers or components as
hereinafter described. The length and width of any particular one (or pair) of the
laminated insole insert 1 may vary as is customary, depending upon the size of
footwear for which that laminated insole insert 1 is intended.
14 If desired, the upper surface 13 of the body member 11 may be overlaid with a
thin fabric liner or other suitable pliable sheet-like material, to separate the sole of the
wearer's foot from direct contact with the body member 11; such a liner may be
constructed of an odor and/or moisture absorbing material, as known in the art, and
may also be impregnated with an antibacterial and/or antimicrobial agent.
The material from which an upper member 25 of the body member 11 is
molded or otherwise formed is preferably a pliable substance that provides the desired
cushioning, lightweightness, physical strength, wearability, rot resistance, slip
resistance, durability for long use, and relative inertness including not commonly the
cause of allergic reactions when in contact with skin. Preferably, the material selected
is also one that is trimmable with a pair of scissors or shears for more precisely
adapting, or custom fitting, the laminated insole insert 1 to the footwear for which it is
intended.
The upper member 25 generally has a uniform thickness, a preferred material
therefor being that provided under the trademark "POLIYOU" of Kun Chyang Ent.
Co., Ltd., which includes structure and properties that make unnecessary the use of a
liner as hereinbefore mentioned. For example, the upper member 25 of an exemplary
one of laminated insole inserts 1 has a thickness of approximately 4 mm.
Various dimensions are quantified here below for exemplary purposes only;
those quantities were observed for a laminated insole insert 1 of the present invention
for an oxford-type shoe, sometimes referred to herein as the "exemplary specimen". It
15 is to be understood that those dimensions may increase or decrease according to the
shoe size for which a particular set of the laminated insole inserts 1 is to be utilized.
For purposes of reference herein, regions of the upper member 25 are defined
as a toe edge 27, a heel edge 33, a medial side edge 35, and a lateral side edge 37
corresponding to parts of the user's foot. The upper member 25 includes a heel
portion 43, having a lateral portion 45 and a medial portion 47, and an arch portion 53.
The body member 11 also includes a lower member 55, generally constructed of the
same type of material as the upper member 25, preferably the "POLIYOU" material,
that is laminated or otherwise secured to, the upper member 25 as hereinafter
described. The lower member 55 may have the same thickness as the upper member
25 or, alternatively, the lower member 55 may be thicker or thinner than the upper
member 25. For example, in one of the exemplary specimens, the lower member
55 has a thickness of approximately 6 mm.
The body member 11 preferably has a Type C (commonly referred to as
"Shore C Scale") durometer hardness measured in accordance with American
Society of Testing and Material (ASTM) standard D 2440-97 of less than about 70
and more preferably a hardness in a range of about 40-60. Depending upon the
particular activity for which the footwear is intended, however, the hardness may be
greater or lesser as desired. For example, if the footwear is intended for walking,
the body member 11 may have a Type C durometer hardness (ASTM D 2240-97) of
about 45, whereas if the footwear is intended for running, the body member 11 may
16 have a hardness of about 60. In short, the body member 11 should be sufficiently
"soft" to provide shock attenuation, but sufficiently firm to provide stability to the
foot.
The lower member 55 has a front edge 57, a heel edge 63, a medial side edge
65, and a lateral side edge 67. The heel edge 63, the medial side edge 65, and the
lateral side edge 67 of the lower member 55 are profiled and dimensioned to fit just
within the corresponding sides 69, and in abutting engagement with the insole 17, of
the shoe 23, as shown in Fig. 5. Further, the toe edge 27, the medial side edge 35,
and the lateral side edge 37 of the upper member 25 that are distally spaced from the
medial side edge 65 and the lateral side edge 67 of the lower member 55 are also
profiled and dimensioned to fit just within the corresponding sides 69 and toe of the
shoe 23.
The lateral portion 45 of the upper member 25 extends forwardly along the
lateral side edge 37, as shown in Figs. 2 and 3, to terminate at a foremost end 73
thereof. Further, the lateral portion 45 extends transversely outwardly from the lower
member 55, beginning approximately at a rearmost part 75 of the upper member 25
and continuing alongside the lateral side edge 67 to the foremost end 73 to thereby
form a lateral heel flap 77 that is displaced upwardly against a lateral side 83 of the
shoe 23 when inserted therein, as shown in Figs. 4 and 5.
Similarly, the medial portion 47 of the heel portion 43 extends forwardly along
the medial side edge 35 to join the arch portion 53, as shown in Figs. 2 and 3. The
medial portion 47 extends transversely outwardly from the lower member 55,
17 beginning approximately at the rearmost part 75 of the upper member 25 and
continuing alongside the medial side edge 65 to the arch portion 53 to thereby form a
medial heel flap 85 that is displaced upwardly against a medial side 87 of the shoe 23
when inserted therein, as shown in Fig. 5. Such upward displacement of the lateral
portion 45 and the medial portion 47 when inserted in the shoe 23 substantially
increases the effective thickness of the upper member 25 in, and therefore
substantially increases the operative support provided by, the lateral portion 45 and the
medial portion 47 of the heel portion 43.
Similarly, the arch portion 53 extends forwardly along the medial side edge 35
from the medial portion 47 of the heel portion 43 to terminate just rearwardly of the
first metatarsal phalangeal joint Jl at a foremost end 93 thereof, as shown in Figs. 2
and 3. Further, the arch portion 53 extends transversely outwardly from the lower
member 55, beginning at medial portion 47 of the heel portion 43 and continuing
alongside the medial side edge 65 to the foremost end 93 to thereby form an arch flap
95 that is displaced upwardly against the medial side 87 of the shoe 23 when inserted
therein, as shown in Fig. 5. Again, such upward displacement of the arch portion 53
when inserted in a shoe substantially increases the effective thickness of the upper
member 25 in, and therefore substantially increases the operative support provided by,
the arch portion 53.
As an example of dimensions for the heel portion 43 and the arch portion 53 of
one of the exemplary specimens of the laminated insole insert 1, the transverse width
of the lateral portion 45 of the heel portion 43 is approximately 1.3 cm, or
18 approximately sixteen percent of the width of the upper member 25 corresponding to
the metatarsal joints; the transverse width of the medial portion 47 of the heel portion
43 is approximately 0.9 cm, or approximately eleven percent of the width of the upper
member 25 corresponding to the metatarsal joints; the maximum transverse width of
the arch portion 53 is approximately 2.0 cm, or approximately twenty-five percent of
the width of the upper member 25 corresponding to the metatarsal joints; the foremost
end 73 of the lateral portion 45 of the heel portion 43 is spaced approximately 9.0
centimeters forwardly from the rearmost part 75 of the heel, or approximately forty
percent of the overall length of the upper member 25; the medial portion 47 of the heel
portion 43 extends forwardly to approximately 7.0 centimeters in front of the rearmost
part 75 of the heel, or approximately thirty percent of the overall length of the upper
member 25; and the foremost end 93 of the arch portion 53 is spaced approximately
14.5 centimeters forwardly from the rearmost part 75 of the heel, or approximately
sixty percent of the overall length of the upper member 25.
It is to be understood that the medial portion 47 of the heel portion 43 may
comprise a single flap or, alternatively, the medial portion 47 may be separated from
the arch portion 53 if desired, as indicated by a phantom line designated by the
numeral 97 in Fig. 3.
The front edge 57 of the lower member 55 is dimensioned and configured to
terminate just rearwardly from the second through fifth metatarsal phalangeal joints to
provide necessary stability and support therefor, and particularly support for the
second and third such joints. The lower member 55 also includes a metatarsal cutout
19 103 having a longitudinal side 105 operatively spaced between a user's first and
second metatarsal phalangeal joints Jl, J2, and a transverse side 107 dimensioned and
configured to be spaced rearwardly from the first metatarsal phalangeal joint to
thereby reduce support for the first metatarsal phalangeal joint and to thereby allow
that joint and the sesamoids there below to appropriately plantar flex between
midstance and toe-off phases of a user's gait.
In addition, the lower member 55 has a heel cutout 113 operatively spaced
below a central portion of a user's heel whereat the greatest weight-generated forces
are normally applied. For example, the heel cutout 113 of one of the exemplary
specimens has a generally circular or ovular shape, with an overall fore-and-aft
dimension of approximately 2.0 centimeters and an overall transverse dimension of
approximately 2.3 centimeters, or dimensions of approximately forty to forty-six
percent of the transverse width of the lower member 55 at the center of the heel cutout
113.
Briefly stated, the heel portion 43 and the arch portion 53 are configured and
dimensioned to cooperatively redistribute greater weight-generated forces normally
bearing against the central, more bony regions of the heel of a user's foot, that are
normally induced during various supported phases of the user's gait, outwardly toward
the larger and more fleshy regions of the user's heel that normally experience smaller,
weight-generated forces to thereby substantially reduce the range of such forces
bearing against the sole of the user's foot. In other words, the heel portion 43 and the
arch portion 53, in conjunction with the heel cutout 113, are configured to redistribute
20 the weight- generated forces from the center of the user's heel outwardly to thereby
reduce or eliminate the incidence of bruising at the bottom center of the user's heel.
The metatarsal cutout 103 is configured to permit the user's first metatarsal-
phalangeal joint Jl to move vertically downwardly while walking. The metatarsal
cutout 103, which is generally spaced such that the user's first metatarsal phalangeal
joint Jl is spaced approximately centrally there over, is configured to have sufficient
horizontal dimensions to properly accommodate the user's paired sesamoid bones
located beneath his first metatarsal joint Jl to thereby allow proper, natural flexion of
the user's metatarsal phalangeal joints despite the user's foot being confined to an
article of footwear.
More specifically, the metatarsal cutout 103 permits the first metatarsal
phalangeal joint Jl to be displaced more naturally relative to the adjacent metatarsals
to promote increased stability and greater balance to the extrinsic musculature of the
foot and to minimize or eliminate the incidence of saddle joint deformity.
Operatively depressing the upper member 25 into the metatarsal cutout 103 is also
configured to basically cup the first metatarsal phalangeal joint Jl to thereby
essentially lock the support provided by the laminated insole insert 1 securely in the
footwear against the user's foot and, additionally, to prevent forward slippage of the
user's foot in the footwear.
It is to be understood that the metatarsal cutout 103 may be approximately
trapezoidally shaped, as suggested in Fig. 3, or circular, rectangular, triangular, oval,
or any other suitable shape so long as the metatarsal cutout 103 is properly
21 dimensioned to. cooperatively with other components of the laminated insole insert 1,
accomplish desired foot functioning and redistribution of the weight-generated forces
bearing against the sole of the user's foot during the various phases of gait as
described herein.
The arch portion 53, in conjunction with the metatarsal cutout 103, is
configured to permit weight-generated forces to be more naturally distributed
between the user's arch and the various metatarsals to thereby minimize or eliminate
the incidence of tibial sesamoiditis. Further, the arch portion 53 and the metatarsal
cutout 103 are configured such that cooperative interaction therebetween reduces
first ray instability by supporting the talonavicular joint which, in turn, reduces the
stress on adjacent metatarsals thereby decreasing or eliminating the incidence of
metatarsal stress fractures. Also, the arch portion 53 is configured to promote more
natural control of the talonavicular joint to thereby decrease or eliminate the
incidence of shin splints and fatigue of the front and back leg muscles, and to
thereby promote more efficient movement of the user's lower leg muscles.
The operative structural and contour features of the laminated insole insert 1,
namely the metatarsal cutout 103, the heel portion 43, and the arch portion 53 are
configured to cooperatively provide the laminated insole insert 1 with the ability to
permit a user's foot to be secure and stable as necessary for appropriate flexing and
movement of the bone structure throughout the phases of gait in most existing
footwear that do not otherwise provide such security and stability. As an added
22 benefit of the laminated insole insert 1 , the metatarsal cutout 103, the heel portion
43, and the arch portion 53 are configured such that cooperative interaction there
among largely minimizes or eliminates excessive inward rotation of the user's leg to
thereby reduce knee and hip discomforts sometimes associated therewith. Further,
and particularly for users having flat feet, the body member 11, the metatarsal
cutout 103, the heel portion 43, and the arch portion 53 are configured such that
cooperative interaction there among will more naturally balance the extrinsic
muscles on the top and bottom of the user's foot to thereby minimize or entirely
eliminate the maladies commonly referred to as bunions and hammertoes.
A state-of-the-art system, developed for measuring the distribution of weight-
generated forces applied to the sole of a user's foot, sometimes referred to as "F-
scan in-shoe gait analysis", was used to evaluate the inventive features of the
laminated insole insert 1 of the present invention. The F-scan system uses paper-
thin insole devices, each approximately 0.007-inch thick and containing on the order
of a thousand individual sensors. The F-scan insole devices are flexible and
trimmable to custom fit almost any shoe size or shape, including children's shoes.
During evaluations, the F-scan insoles are attached directly to the bottom of a sock
or the skin of a child's sole before insertion into footwear. The bi-pedal plantar
pressures at each of the sensors are then detected, monitored, and recorded by the
F-scan system as they sequentially occur during a normal gait cycle and/or during
stance. The results may then be compared with similar measurements taken with the
23 same or similar footwear, one set with modifications such as the laminated insole
insert 1 , and one set without such modifications.
In regard to the present invention, F-scan computerized gait analysis system
was used for diagnostic evaluations of footwear not providing the benefits of the
laminated insole insert 1 and compared with corresponding diagnostic evaluations of
footwear utilizing the laminated insole insert 1 of the present invention. The
comparison of the sets of analyses disclosed that the greatest weight-generated forces
normally applied to localized regions of the user's foot were indeed redistributed
toward other regions of the user's foot sole normally experiencing smaller weight-
generated forces to thereby substantially reduce the range of applied weight-
generated forces.
In an application of the present invention wherein the laminated insole insert 1
is appropriately installed in existing footwear and worn on a user's foot, some of the
primary benefits provided by the laminated insole insert 1 while walking and running
begin at heel strike, when the heel of the user's footwear first hits the underlying
supporting surface. The resiliency of the lateral portion 45 of the heel portion 43 of
the laminated insole insert 1 , in addition to cooperatively redistributing weight-
generated forces applied to the user's foot as described herein, also provides
cushioning for those initial impacts to thereby reduce risk of injury to the user and
to thereby support and promote enhanced efficiency of other associated parts of the
user's foot and lower skeletal structure.
24 After each such initial impact, the user's foot pivots distally about his heel,
with the lateral sides of his arch and forefoot impacting against the underlying
supporting surface and his foot pronating to a neutral position with the central
vertical plane of his heel generally appropriately oriented perpendicularly to the
underlying supporting surface. Again, resiliency of the arch portion 53 and the
body member 11 of the laminated insole insert 1 provides cushioning for the shocks
arising from such secondary impacts. As the user's metatarsal phalangeal joints shift
downwardly, the first metatarsal phalangeal joint stabilizes as it must before the user's
foot subsequently lifts from the underlying supporting surface. The lesser phalangeal
joints are accordingly stabilized due to the contours of the lower member 55, including
the metatarsal cutout 103 for the first metatarsal phalangeal joint Jl as herein
described.
The resiliency of the body member 11 beneath the user's metatarsal heads
M1-M5 also serves to redistribute weight-generated forces applied there against
during mid-stance through propulsive phases of his gait cycle. The described
motion places the user's foot in an appropriate biomechanical position for the
propulsive phase of his gait cycle, including proper displacing of his sesamoid
apparatus during mid-stance and toe-off phases. In addition, the cooperative
interaction by the heel portion 43, the arch portion 53, and the body member 11
allows the sesamoids and certain muscles of the user's foot to momentarily rest to
thereby create a desirable timing sequence thereof and, particularly in conjunction
25 with the metatarsal cutout 103, to create a more effective lever system just prior to the
foot progressing into the toe-off phase of his gait.
As the user's foot rotates forwardly into the toe-off phase, the first metatarsal
Ml is permitted by the interaction between the upper member 25 and the lower
member 55 to be appropriately pushed downwardly, remaining stable, particularly due
to the support provided to the second and third metatarsals by the lower member 55 as
the user's heel lifts from the underlying supporting surface, and continuing to remain
stable and appropriately flex without forward slippage up to the position in the user's
gait whereat the first metatarsal phalangeal joint Jl lifts from the underlying
supporting surface. In other words, as the user's heel lifts from the underlying
supporting surface, the laminated insole insert 1 allows the user's first metatarsal
phalangeal joint Jl to actually displace downwardly to continue to be stabilized,
thereby progressively providing appropriate functioning of the user's foot throughout
the entire supported phases of his gait.
One of the primary reasons the user's foot remains stable throughout the
supported phases of his gait is because the structure of the laminated insole insert 1
provides support and stability for each of the user's heel, arch, and first metatarsal
from before the user's foot rotates forwardly, whereat his heel lifts from the
underlying supporting surface, to the point in the user's gait whereat the user's first
metatarsal actually lifts from the underlying supporting surface. Thus, the laminated
insole insert 1 appropriately provides all of the necessary supporting and stabilizing
26 factors while allowing the user's foot to function appropriately within the confines of
his shoe.
In other words, the laminated insole insert 1 is adapted to support and
maintain the heel in a perpendicular orientation relative to the underlying supporting
surface to thereby support the longitudinal arch of the foot by shifting the weight
laterally, to provide a larger surface area to balance the user's weight as well as to
provide a more even distribution of weight-generated forces applied to the sole of
his feet, and to allow his foot to function more efficiently by allowing the first
metatarsal phalangeal joint and associated sesamoid apparatus to function properly.
It should now be obvious from the foregoing that the material properties of
the various regions of the laminated insole insert 1 appropriately cushion, support
and stabilize various parts of the user's foot as herein described. It should also now
be obvious that the resiliencies hereinbefore described may be altered, depending
upon the intended use of the footwear for which the laminated insole insert 1 is
intended. For example, adult footwear designed for use in situations where the
wearer will frequently be carrying a heavy load (e.g., work boots) may require
more support than a child's dress shoe. Likewise, footwear made for mnning may
require firmer support in the heel section to thereby absorb the greater initial shock
of each running step than would a hiking boot in which more cushioning may be
desired for each walking step. Further, it will be appreciated that the present
invention is not limited necessarily to any particular type of footwear and may be
equally desirable for use in shoes and boots.
27 Use of the laminated insole insert 1 of the present invention in a child's shoe
will preferably be initiated as soon as the infant's feet become weight-bearing to
thereby aid the child in standing and walking, to mold the child's foot into an
appropriate position that does not interfere with the foot's normal ontogenetic
development, and to provide substantially full and complete support between the
child's foot and the underlying supporting surface.
A first modified embodiment of the laminated insole insert in accordance with
the present invention is shown in Figs. 6 through 8 and is generally designated by
the numeral 119. Many of the characteristics of the first modified embodiment 119
are substantially similar to those of the previously described embodiment 1 and will
not be reiterated here in detail.
The first modified embodiment 119, adapted for insertion in a wearer's shoe
121, generally comprises a body member 123 including an upper member 125 having
a toe edge 127, a heel edge 133, a medial side edge 135, and a lateral side edge 137.
The upper member 125 includes a heel portion 143, having a lateral portion 145 and a
medial portion 147, and an arch portion 153. The body member 123 also includes a
lower member 155 that is laminated or otherwise secured to, the upper member 125.
The lower member 155 has a front edge 157, a heel edge 163, a medial side edge 165,
and a lateral side edge 167.
The lateral portion 145 of the upper member 125 extends forwardly along the
lateral side edge 137, as shown in Fig. 6, to terminate at a foremost end 173 thereof.
28 Further, the lateral portion 145 extends transversely outwardly from the lower member
155, beginning approximately at a rearmost part 175 of the upper member 125 and
continuing alongside the lateral side edge 167 to the foremost end 173 to thereby form
a lateral heel flap 177 that is displaced upwardly against a lateral side 183 of the shoe
121 when inserted therein, as shown in Fig. 8.
Similarly, the medial portion 147 of the upper member 125 extends forwardly
along the medial side edge 135 to join the arch portion 153, as shown in Fig. 6. The
medial portion 147 extends transversely outwardly from the lower member 155,
beginning approximately at the rearmost part 175 of the upper member 125 and
continuing alongside the medial side edge 165 to the arch portion 153 to thereby form
a medial heel flap 185 that is displaced upwardly against a medial side 187 of the shoe
121 when inserted therein, as shown in Fig. 8.
Similarly, the arch portion 153 extends forwardly along the medial side edge
135 from the medial portion 147 of the heel portion 143 to terminate just rearwardly of
the first metatarsal phalangeal joint Jl at a foremost end 193 thereof, as shown in Fig.
6. Further, the arch portion 153 extends transversely outwardly from the lower
member 155, beginning at the medial portion 147 of the heel portion 143 and
continuing alongside the medial side edge 165 to the foremost end 193 to thereby form
an arch flap 195 that is displaced upwardly against the medial side 187 of the shoe 121
when inserted therein, as shown in Fig. 8.
The front edge 157 of the lower member 155 is dimensioned and configured to
terminate just rearwardly from the second through fifth metatarsal phalangeal joints to
29 provide necessary stability and support therefor, particularly to the second and third
such joints. The lower member 155 also includes a metatarsal cutout 203 having a
longitudinal side 205 operatively spaced between a user's first and second metatarsal
phalangeal joints Jl, J2, and a transverse side 207 dimensioned and configured to be
spaced rearwardly from the first metatarsal phalangeal joint to thereby reduce support
for the first metatarsal phalangeal joint and to thereby allow that joint and the
sesamoids there below to appropriately plantar flex between midstance and toe-off
phases of a user's gait. In addition, the lower member 155 has a heel cutout 213
operatively spaced below a central portion of a user's heel whereat the greatest
weight-generated forces are normally applied.
The metatarsal cutout 203 is configured to permit the user's first metatarsal
phalangeal joint Jl to move vertically downwardly while walking. The metatarsal
cutout 203, which is generally spaced such that the user's first metatarsal phalangeal
joint Jl is spaced approximately centrally there over, is configured to have sufficient
horizontal dimensions to properly accommodate the user's paired sesamoid bones
located beneath his first metatarsal joint Jl to thereby allow proper, natural flexion of
the user's metatarsal phalangeal joints despite the user's foot being confined to an
article of footwear.
The body member 123 of the first modified embodiment 119 also includes a
metatarsal member 215, generally constructed of the same type of material as the
lower member 155, preferably the "POLIYOU" material, that is laminated or
otherwise secured to the lower member 155, as shown in Figs. 6 and 7. The
30 metatarsal member 215 may have the same thickness as the upper member 125, the
lower member 155, or any other suitable thickness, as desired. The metatarsal
member 215 has a front edge 217 that is approximately transversely aligned with the
transverse side 207 of the metatarsal cutout 203. The metatarsal member 215 is
dimensioned and configured to provide further support for at least the second and
third metatarsals. In addition, the metatarsal member 215 is dimensioned and
configured to, in conjunction with the upper member 125, the lower member 155,
and particularly the metatarsal cutout 203, allow the sesamoids and associated
muscles of the user's foot to momentarily rest during the mid-stance phase of the
user's gait to thereby create a desirable timing sequence thereof and to create a more
effective lever system just prior to the foot progressing into the toe-off phase. For
example, one of the exemplary specimens has an overall fore-and-aft dimension of
approximately 5.0 centimeters, or approximately twenty percent of the overall length
of the insole insert 119.
In regard to the first modified embodiment 119 of the present invention, F-scan
computerized gait analysis system was used for diagnostic evaluations of footwear not
providing the benefits of the first modified embodiment 119 and compared with
corresponding diagnostic evaluations of footwear utilizing the first modified
embodiment 119 of the present invention. Again, the comparison of the sets of
analyses disclosed that the greatest weight-generated forces normally applied to
localized regions of the user's foot sole are indeed redistributed toward other regions
31 of the user's foot sole that normally experiences smaller weight-generated forces to
thereby substantially reduce the range of applied weight-generated forces.
A second modified embodiment of the laminated insole insert in accordance
with the present invention is shown in Figs. 9 through 12 and is generally designated
by the numeral 219. Many of the characteristics of the second modified
embodiment 219 are substantially similar to those of the previously described
embodiments and will not be reiterated here in detail.
The second modified embodiment 219, adapted for insertion in a wearer's shoe
221, generally comprises a body member 225 having a toe edge 227, a heel edge 233,
a medial side edge 235, and a lateral side edge 237. The body member 225 includes a
heel portion 243, having a lateral portion 245 and a medial portion 247, and an arch
portion 253. The second modified embodiment 219 also includes an arch member 255
that is laminated or otherwise secured to, the body member 225.
The lateral portion 245 of the body member 225 extends forwardly along the
lateral side edge 237, as shown in Fig. 9, to terminate at a foremost end 273 thereof.
Further, the lateral portion 245 extends transversely outwardly beginning
approximately at a rearmost part 275 of the body member 225 and continuing
alongside the lateral side edge 237 to the foremost end 273 to thereby form a lateral
heel flap 277 that is displaced upwardly against a lateral side 283 of the shoe 221
when inserted therein, as shown in Fig. 11.
Similarly, the medial portion 247 of the heel portion 243 of the body member
225 extends forwardly along the medial side edge 235 to join the arch portion 253.
32 The medial portion 247 extends transversely outwardly beginning approximately at
the rearmost part 275 of the body member 225 and continuing alongside the medial
side edge 235 approximately to the arch portion 253 to thereby form a medial heel flap
285 that is displaced upwardly against a medial side 287 of the shoe 221 when inserted
therein.
Similarly, the arch portion 253 extends forwardly along the medial side edge
235 approximately from the medial portion 247 of the heel portion 243 to terminate
just rearwardly of the first metatarsal phalangeal joint Jl at a foremost end 293
thereof. Further, the arch portion 253 extends transversely outwardly beginning at the
medial portion 247 of the heel portion 243 and continuing alongside the medial side
edge 235 to the foremost end 293.
The arch member 255 is adapted to underlie and support the second and third
(and fourth, if desired) metatarsal necks N2, N3. An inner extent of the arch
member 255 essentially defines a boundary, designated by the numeral 303 in Figs.
9 and 10, having a fore medial segment 305, an intermediate segment 307, and an
aft medial segment 313. The fore medial segment 305 of the boundary 303 is offset
rearwardly with respect to the intermediate segment 307 of the boundary 303 to
accommodate the first metatarsal head. The fore medial segment 305 passes
approximately or directly beneath the neck of the first metatarsal head, and the
intermediate segment 307 passes approximately or directly beneath the necks of the
second, third and perhaps fourth metatarsal necks.
33 In accordance with the present invention, the arch member 255 and the body
member 225 of the second modified embodiment 219 are cooperatively dimensioned
and configured such that (i) a softer resilient material is located in the region of the
user's heel, the lateral region of the user's arch, and the user's forefoot and toe
regions, and (ii) a harder resilient material located in the medial region of the user's
arch region and the user's second, third and perhaps fourth metatarsal regions, as
illustrated in Figs. 1 , 9, 10 and 12, which show the softer material in the form of
the body member 225 and the harder material in the form of the arch member 255,
with the arch member 225 secured to the underside of the arch portion 253 and other
areas of the body meber 225 adjacent thereto. Fig. 11 shows the second modified
embodiment 219 inserted in the shoe 221.
The body member 225 of softer material preferably has a Type C (commonly
referred to as "Shore C Scale") durometer hardness measured in accordance with
American Society of Testing and Material (ASTM) standard D 2440-97 of less than
about 70 and more preferably a hardness in a range of about 40-60. Depending
upon the particular activity for which the footwear is intended, however, the
hardness may be greater or lesser as desired. For example, if the footwear is
intended for walking, the body member 225 may have a Type C durometer hardness
(ASTM D 2240-97) of about 45, whereas if the footwear is intended for running,
the body member 225 may have a hardness of about 60. In short, the body member
225 should be sufficiently "soft" to provide shock attenuation, but sufficiently firm
to provide stability to the foot. The arch member 225 of harder material preferably
34 has a Type C durometer hardness (ASTM D 2240-97) of 50-85, and preferably
greater than about 60. For footwear (e.g. work boots) subjected to heavy loading,
the body 42 preferably has a hardness of about 75.
The two components of the second modified embodiment 219, namely the
body member 225 and the arch member 255, may be bonded to one another in any
suitable manner, such as by heat fusion, adhesive, or by a chemical or curing
process. The arch member 255 can be formed of any suitable material, such as
polyurethane, TPR, PVC, EVA or other material well known to those of ordinary
skill in the art of footwear. In addition, the body member 225 and the arch member
255 may be constructed of different colored materials to thereby enhance the
aesthetic characteristics of the second modified embodiment 219, for example,
and/or to highlight the use of multiple materials for marketability.
The softer material of the body member 225 compresses relatively easily
when loaded. However, the harder material of the arch member 255 does not
compress as easily when loaded. Therefore, the areas of the body member 225 are
configured to, among other things, deflect to absorb impact forces, whereas the
areas of the arch member 255 are configured to, among other things, more
diligently resist compression and thereby provide firmer support for the arch region
of the user's foot.
In other words, the arch member 255 firmly supports the osseous alignment
of the user's foot when in the neutral position thereby relieving stress in the
ligaments, muscles and tendons which maintain the foot in this position. During
35 toe-off, the arch member 255 provides necessary support for the second and third
(and perhaps fourth, N4) metatarsal necks N2, N3, but the softer material of the
body member 225 permits the first metatarsal neck Nl and head Ml to plantarflex
relative to the second and third metatarsal heads M2, M3.
As shown in Fig. 1 , the aft medial segment 313 of the second modified
embodiment 219 extends generally between the third and fourth metatarsal necks
N3, N4, continues rearwardly approximately beneath the juncture between the
cuboid bone 315 and the lateral cuniform bone 317, and curves gradually in a
rearward and medial direction to the medial side edge 235 passing approximately
beneath the juncture between the navicular bone 323 and the forward end of the
medial tuberosity 325 of the user's heel such that the body member 225 provides
cushioning for the entire heel area.
Briefly stated, the second modified embodiment 219 of the present invention
comprises a first softer material positioned for attenuating the impact forces applied
to the user's foot and other skeletal structures during standing, walking and running,
and a second harder material for firmly supporting the user's foot.
The body member 225, located distally from the arch member 255, interacts
with the first, second, third, fourth and fifth metatarsal heads, whereas the arch
member 255 provides support for the metatarsal necks, proximal phalanges and
metatarsal phalangeal joints associated with the second and third metatarsal heads.
The structural design of the second modified embodiment 219 provides
stability to the rear and mid foot regions, and simultaneously provides the transverse
36 plane of the forefoot with uninhibited, enhanced motion, accomplished at the
metatarsal phalangeal joints.
In regard to the second modified embodiment of the present invention, F-scan
computerized gait analysis system was used for diagnostic evaluations of footwear not
providing the benefits of the second modified embodiment 219 and compared with
corresponding diagnostic evaluations of footwear utilizing the second modified
embodiment 219 of the present invention. The comparison of the sets of analyses
disclosed that the greatest weight-generated forces normally applied to localized
regions of the user's foot sole are indeed redistributed toward other regions of the
user's foot sole that normally experience smaller weight- generated forces to thereby
substantially reduce the range of applied weight generated forces.
It is to be understood that while certain forms of the present invention have
been illustrated and described herein, it is not to be limited to the specific forms or
arrangement of parts described and shown.
37

Claims

CLAIMSWhat is claimed and desired to be secured by Letters Patent is as follows:
1. An insole insert for a user's footwear, said insole insert comprising: a body
having a upper member with a heel portion, a toe edge, a heel edge, a lateral
side edge, and a medial side edge, said heel portion including a medial
portion extending along said heel edge and said medial side edge, and a
lateral portion extending along said heel edge and said lateral side edge, of
said upper member; said upper member constructed of flexible material and
configured such that said medial portion and said lateral portion are
displaceable upwardly alongside respective medial and lateral sides of the
user's footwear to operatively and cooperatively redistribute weight-generated
forces operatively bearing against the heel of the user's foot such that greater
weight-generated forces normally bearing against certain regions of the heel
of the user's foot are substantially reduced and redistributed toward other
regions of the user's foot whereat normally smaller weight-generated forces
normally bear against the user's foot.
2. The insole insert of claim 1 , wherein said upper member has a substantially
uniform thickness.
38
3. The insole insert of claim 2, wherein said upper member has a thickness of
approximately four millimeters.
4. The insole insert of claim 1, wherein said body member further includes a
lower member connected to said upper member.
5. The insole insert of claim 4, wherein said upper member and said lower
member each have a substantially uniform thickness.
6. The insole insert of claim 5, wherein the thickness of said lower member is
different from the thickness of said upper member.
7. The insole insert of claim 5, wherein said lower member has a thickness of
approximately six millimeters.
8. The insole insert of claim 5, wherein the thickness of said lower member is
greater than the thickness of said upper member.
9. The insole insert of claim 4, wherein said body member further includes a
metatarsal member connected to said lower member.
39
10. The insole insert of claim 9, wherein said metatarsal member has a
substantially uniform thickness.
11. The insole insert of claim 4, including a metatarsal cutout in said lower
member, said metatarsal cutout dimensioned and configured to be generally
operatively centered beneath the user's first metatarsal joint.
12. The insole insert of claim 11 , wherein said metatarsal cutout has a
longitudinal side spaced operatively between the user's first and second
metatarsal phalangeal joints.
13. The insole insert of claim 11, wherein said metatarsal cutout has a transverse
side spaced operatively just rearwardly from the user's first metatarsal
phalangeal joint.
14. The insole insert of claim 13, wherein said metatarsal cutout has a transverse
side that is approximately transversely aligned with said front edge of said
metatarsal member.
15. The insole insert of claim 11 , wherein said upper member, said lower
member, and said metatarsal cutout are dimensioned and configured to
cooperatively allow the user's first metatarsal phalangeal joint and his
40 sesamoids there below to appropriately plantarflex between the midstance and
toe-off phases of the user's gait.
16. The insole insert of claim 11 , wherein said metatarsal cutout is configured to
have an approximately trapezoidal shape.
17. The insole insert of claim 4, including a heel cutout in said lower member,
said heel cutout generally operatively centered beneath the user's heel
whereat the greatest weight-generated forces are normally applied.
18. The insole insert of claim 4, further including said lower member having a
front edge operatively spaced just rearwardly from at least the user's second
and third metatarsal phalangeal joints.
19. The insole insert of claim 4, further including said lower member having a
front edge operatively spaced just rearwardly from the user's second through
fifth metatarsal phalangeal joints.
20. The insole insert of claim 1 , wherein said body member further includes an
arch portion extending forwardly from said medial portion along said medial
side edge wherein said arch portion is configured to be displaceable upwardly
alongside the medial side of the user footwear to, cooperatively with said
41 medial portion and said lateral portion, redistribute weight-generated forces
operatively bearing against the sole of the user's foot such that greater
weight-generated forces normally bearing against certain regions of the sole
of the user's foot are substantially reduced and redistributed toward other
regions of the user's foot whereat normally smaller weight-generated forces
normally bear against the user's foot.
21. The insole insert of claim 20, wherein said heel portion and said arch portion
are configured to cooperatively redistribute the greater weight-generated
forces normally applied to the inner and more bony regions of the user's heel
outwardly toward the outer and more fleshy regions of the user's heel.
22. The insole insert of claim 1 , wherein said medial portion and said lateral
portion are configured to operatively effectively increase the thickness thereof
when said insole insert is inserted in the user's footwear.
23. The insole insert of claim 1, wherein said medial portion and said lateral
portion are configured to operatively increase the support provided thereby
when said insole insert is inserted in the user's footwear.
42
24. An insole insert for a user's footwear, said insole insert comprising:
(a) a body having
(1) a upper member, constructed of flexible material having a
substantially uniform thickness, with a heel portion, an arch
portion, a toe edge, a heel edge, a lateral side edge, and a
medial side edge, said heel portion including a medial portion
extending along said heel edge and said medial side edge, and a
lateral portion extending along said heel edge and said lateral
side edge of said upper member; said arch portion extending
forwardly from said medial portion along said medial side edge;
said medial portion and said arch portion configured to be
displaceable upwardly alongside the medial side of the user
footwear, and said lateral portion configured to be displaceable
upwardly alongside the lateral side of the user footwear, to
operatively and cooperatively redistribute weight-generated
forces operatively bearing against the sole of the user's foot
such that greater weight-generated forces normally bearing
against certain regions of the sole of the user's foot are
substantially reduced and redistributed toward other regions of
the user's foot whereat normally smaller weight-generated
forces normally bear against the user's foot;
43 (2) a lower member, having a substantially uniform thickness,
connected to said upper member and a front edge operatively
spaced just rearwardly from at least the user's second and third
metatarsal phalangeal joints
(b) a metatarsal member, having a substantially uniform thickness,
connected to said lower member; said metatarsal member having a
transversely oriented front edge;
(c) a metatarsal cutout in said lower member, said metatarsal cutout
dimensioned and configured to be generally operatively centered
beneath the user's first metatarsal joint, said metatarsal cutout having:
(1) a longitudinal side spaced operatively between the user's first
and second metatarsal phalangeal joints, and
(2) a transverse side, spaced operatively just rearwardly from the
user's first metatarsal phalangeal joint and approximately
transversely aligned with said front edge of said metatarsal
member; and
(d) a heel cutout in said lower member, said heel cutout generally
operatively centered beneath the user's heel whereat the greatest
weight-generated forces are normally applied; and
(e) wherein said upper member, said lower member, and said metatarsal
cutout are dimensioned and configured to cooperatively allow the
user's first metatarsal phalangeal joint and his sesamoids there below
44 to appropriately plantarflex between the midstance and toe-off phases
of the user's gait.
25. The insole insert of claim 24, further including:
(a) said upper member having an arch portion; and
(b) an arch member, constructed of harder material than said upper
member and connected to an underside of said arch portion, that is
configured to operatively provide support for at least the second and
third metatarsal necks of the user's foot and for the user's arch, said
arch member configured to provide said support throughout supported
phases of the user's gait.
26. The insole insert of claim 25, wherein said arch member comprises a
boundary having a fore medial segment and an intermediate segment, wherein
said intermediate segment is configured to operatively pass approximately
beneath at least the second and third metatarsal necks of the user's foot, and
said for medial segment is configured to operatively pass approximately
beneath the first metatarsal neck of the user's foot.
27. The insole insert of claim 25, wherein said arch member comprises a
boundary having an aft medial segment configured to operatively extend
generally between user's third and fourth metatarsal necks, continue
45 rearwardly approximately beneath the juncture between user's cuboid bone
and lateral cuniform bone, and curve gradually rearwardly and medially to
said medial side edge to pass approximately beneath the juncture between the
user's navicular bone and the forward end of the medial tuberosity of the
user's foot.
46
PCT/US1999/008521 1998-04-17 1999-04-16 Laminated insole insert for footwear WO1999053786A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU37507/99A AU3750799A (en) 1998-04-17 1999-04-16 Laminated insole insert for footwear

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US6203598A 1998-04-17 1998-04-17
US09/062,035 1998-04-17

Publications (1)

Publication Number Publication Date
WO1999053786A1 true WO1999053786A1 (en) 1999-10-28

Family

ID=22039804

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/US1999/008521 WO1999053786A1 (en) 1998-04-17 1999-04-16 Laminated insole insert for footwear

Country Status (2)

Country Link
AU (1) AU3750799A (en)
WO (1) WO1999053786A1 (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2002082937A1 (en) * 2001-04-11 2002-10-24 International Podiatrist Consulting (Societe A Responsabilite Limitee) Absorbent and desorbent device
FR3031036A1 (en) * 2014-12-29 2016-07-01 Guy Sparacca BIOLOGICAL POCOLOGICAL ORTHESIS

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2425837A (en) * 1944-09-04 1947-08-19 William M Scholl Cuboid support and heel retainer
US5146698A (en) * 1989-05-08 1992-09-15 Tilles Harvey G Shoe insole proform II
US5463824A (en) * 1993-06-16 1995-11-07 Barna; Randall S. Arch support system and method for manufacture and use
US5542196A (en) * 1994-04-15 1996-08-06 Donna Karan Shoe Company Insole
US5746011A (en) * 1994-10-24 1998-05-05 Ortolab Ab Orthopedic insole and method of its manufacture

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2425837A (en) * 1944-09-04 1947-08-19 William M Scholl Cuboid support and heel retainer
US5146698A (en) * 1989-05-08 1992-09-15 Tilles Harvey G Shoe insole proform II
US5463824A (en) * 1993-06-16 1995-11-07 Barna; Randall S. Arch support system and method for manufacture and use
US5542196A (en) * 1994-04-15 1996-08-06 Donna Karan Shoe Company Insole
US5746011A (en) * 1994-10-24 1998-05-05 Ortolab Ab Orthopedic insole and method of its manufacture

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2002082937A1 (en) * 2001-04-11 2002-10-24 International Podiatrist Consulting (Societe A Responsabilite Limitee) Absorbent and desorbent device
FR3031036A1 (en) * 2014-12-29 2016-07-01 Guy Sparacca BIOLOGICAL POCOLOGICAL ORTHESIS

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