Patent Document

CROSS-REFERENCE TO RELATED APPLICATIONS 
   This application is a continuation-in-part of, and claims benefit of, co-pending U.S. application Ser. No. 09/866,818, filed May 29, 2001, entitled, “Ambulatory Leg Suspensory Apparatus.” 

   STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT 
   Not Applicable 
   REFERENCE TO A MICROFICHE APPENDIX 
   Not Applicable 
   BACKGROUND OF THE INVENTION 
   Whenever a doctor prescribes a period with limited or no weight bearing on a single leg or foot, in order to avoid pain or improve healing, the present invention provides an appliance to support the single leg of a patient in a rearward, suspended state while standing on the patient&#39;s other leg. This appliance assists the patient in the prevention of weight bearing. The appliance is designed for use with a below-the-knee cast, a similar strap-on orthopedic boot, an orthopedic shoe, a tennis shoe, or a bandaged foot. The appliance transfers the load of the suspended leg onto the patient&#39;s upper torso and is designed to work in conjunction with a walker or crutches. If the patient loses balance, the appliance includes a breakaway safety fastener designed to open at a pre-determined force. If necessary the patient can use the muscles of the suspended leg to disengage the sling at the breakaway safety fastener, which provides the patient with immediate use of the injured leg to regain balance. Afterward, the safety fastener is easily restored to operational use. 
   As discussed in U.S. Pat. No. 5,882,321, Leg Sling and Abdominal Belt, Fisk (1999), few ambulatory leg slings exist of a prior art. However, an ambulatory leg sling providing a means to disengage and provide the patient immediate use of the injured leg to regain balance has not been disclosed or suggested in the prior art. The Breakaway Leg Sling incorporating the breakaway safety fastener accomplishes this feat. U.S. Pat. No. 2,543,847, Leg sling For Treatment of Unilateral Leg Diseases, Halstedt (1951), disclosed an ambulatory leg sling for use with crutches and provided for suspension of a single leg in a rearward, elevated position. U.S. Pat. No. 2,543,847 was designed to treat a special type of disease, specifically Legg-Perthes disease. In the treatment of this disease, the patient does not wear a cast on the foot and leg but must avoid weight bearing. Mr. Halstedt did not design the Leg Sling For Treatment of Unilateral Leg Diseases to securely, safely encase and ergonomically interface with a below-the-knee cast but rather interface only with the patient&#39;s shoe; this leg sling does not provide a slip free and secure means of encasement for the below-the-knee cast. And, if the patient loses balance while using the Leg Sling For Treatment of Unilateral Leg Diseases, the patient might trip and incur additional injury. As a result, the Halstedt leg sling has not been adopted by the medical community as a means to avoid weight bearing on the foot or ankle healing in a below-the-knee cast or soft orthopedic shoe. 
   U.S. Pat. No. 2,543,847 utilized a single strap with two terminal ends. One terminal end was attached to a single buckle, and the free end of the strap passed through the same buckle twice more to fashion two loops. One loop was placed over the shoulder of the patient on the side opposite of the suspended leg, and the shank of the leg rested in the bottom of the second U-shaped loop thereby providing a means of suspending the leg. U.S. Pat. No. 2,543,847 had several limitations. First, during gait, the U-shaped loop had a tendency to slip along the shank of the leg. Although arm slings successfully used the U-shaped loop as the suspensory means, the U-shaped loop was less effective for suspending the leg because the leg cannot be held as stationary during motion. If the loop slipped during gait, the patient was at risk of bearing weight on the mending leg. Hallstedt recognized this limitation, and he designed a specialized shoe stirrup to minimize slippage. To make the stirrup, a first and second end of another shorter strap were riveted to opposite sides of the suspending U-shaped loop. The new loop comprised the stirrup, and the new loop formed into the stirrup was lodged forward of the heel of the shoe. However, the patient must wear the shoe to complement the stirrup. Without the shoe&#39;s heel, the stirrup was ineffective and the loop slipped. Thus, the stirrup will not work with a cast. The cast is smooth on the plantar side of the foot and does not provide a protruding heel. A cast boot or cast shoe that the patient might wear was not designed with the protruding heel needed to effectively work with the shoe stirrup. Thus, the Leg sling For Treatment of Unilateral Leg Diseases remained an ineffective device for improving the mobility of the patient wearing the leg cast. Further, those skilled in the art, namely Podiatrists and Orthopedic surgeons, have not recognized the Leg Sling For Treatment of Unilateral Leg Diseases as an effective and safe post surgical device to improve the patient&#39;s mobility following surgeries that require the leg cast and a period without weight bearing, such as a bunion correction where the first metatarsal bone of the great toe must be surgically severed, straightened, and re-positioned. Second, the issue of the patient&#39;s safety was not considered in the design since the patient had no means to instantly, effortlessly break apart the Leg Sling For Treatment of Unilateral Leg Diseases to prevent a potential fall with the assistance of the injured leg. Third, to prepare the sling apparatus for use from a sitting position, the patient had to lift the leg and insert the foot through the suspending loop. Once the loop was positioned around the shank of the leg, the specialized shoe stirrup was positioned underneath the heel of the shoe. This process was awkward, time consuming, and difficult in cramped conditions such as the driver&#39;s seat of a vehicle. 
   U.S. Pat. No. 5,882,321, Leg Sling and Abdominal Belt, Fisk (1999), provided another ambulatory leg sling, but a sling designed to accommodate the cast. As seen from the drawings of this prior art, the leg is suspended in a near vertical position with the suspended foot slightly to the rear of the other leg. An abdominal belt was provided to distribute the load of the suspended leg about the patient&#39;s lower torso placing the burden of the load on the hips of the patient. Shoulder straps were included to prevent the upper leading edge of the abdominal belt from rolling and slipping downward. As stated in the claims, the leg sling provided the U-shaped loop in which the sole of the suspended foot contacted the foot receiving means. The upper ends of the U-shaped loop could be anchored at a plurality of potential locations on the abdominal belt. 
   U.S. Pat. No. 5,882,321 had several shortcomings. First, the sling did not provide a means to instantly, effortlessly break apart to prevent a potential fall with the assistance of the injured leg. Second, similar to Hallstedt&#39;s Leg sling For Treatment of Unilateral Leg Diseases, the loop remained the means of suspension, and the sole of the foot rested in the bottom of the U-shaped loop. Third, while the suspended leg remained in a near vertical position, the load distribution carried by the abdominal belt remained more over the hip on the side of the suspended leg. Fourth, the leg sling apparatus required a considerable amount of time to completely remove and return to use. Fifth, the abdominal belt produced discomfort in a large patient, especially when sitting, by constraining the abdominal region. 
   Another device of the prior art is U.S. Pat. No. 5,911,696, Integral Strap Handling Device For A Leg Cast, Coates (1999). U.S. Pat. No. 5,911,696 provided a device for the patient to maneuver a cast, especially a heavy above-the-knee cast, about a bed or similar place of rest. The device was comprised of four straps. The instep strap crossed over the top of the forefoot; the complementing sole strap crossed underneath the sole of the foot. The heel strap crossed behind the heel of the foot. Two rings were used to bind the terminal ends of the three straps together. One ring bound the terminal ends on the lateral side of the ankle, and the other ring bound the terminal ends on the medial side. A means of adjusting the length of each strap was provided. Attached to the instep strap on the top of the forefoot was the assist strap, which provided a means for the patient to grasp the assist strap and maneuver the leg about while resting on the bed or sofa. However, the Integral Strap Handling Device For A Leg Cast did not provide a means to secure the foot apparatus to a load bearing means, and the position of the assist strap on the forefoot was of no value for this purpose. Further, there is no expressed or implied suggestion in this art to modify the Integral Strap Handling Device For A Leg Cast for other than its intended purpose, especially since it is a complete functional unit. However, even if necessary modifications were made to the Integral Strap Handling Device, to include removal of the assist strap and incorporation of an anchor means on the reward section of the heel strap, the Integral Strap Handling Device would produce an inferior result for distributing the forces about a user&#39;s foot while in a rearward, suspended state. In the rearward, suspended state, any anchor modified to fixedly attach to the heel strap must pull against the first and second rings on the sides of the foot with a force equal to the weight of the load, and all forces born by the suspended foot would be transferred through these two rings and about the band encircling the forefoot which is comprised only of the instep and sole straps. With only the forefoot completely encircled, the constant pressure applied at this one location would increase the user&#39;s discomfort since all forces born by the foot would be distributed about this single location. For a user wearing only a bandage covering the foot, this would be quite discomforting. Furthermore, the assist strap could snag an object during the ambulation cycle and cause a fall; removal of the assist strap would but be necessary to improve the user&#39;s safety but would render the Integral Strap Handling Device inoperable for its intended purpose. 
   Another device of the prior art is U.S. Pat. No. 3,739,772, Resilient Harness Device For A Walking Cast, Ennis (1973). The apparatus was comprised of a body harness adapted to extend diagonally across the user&#39;s torso depending from the user&#39;s shoulder on the side opposite the leg cast. Attached to a holding member at the terminal ends of the body harness strap was the first end of a lead strap. A second holder member was fixedly attached to the second end of the lead strap. Engaged to the second holding member on the lower end of the lead strap was a swivel eye spring connector attached by its releasable end. The other non-releasable end of this swivel eye spring connector was fixedly attached to the first distal end of a pull spring; the second distal end of the pull spring was fixedly attached to a second swivel eye spring connector by its non-releasable end. The releasable end of the second swivel eye spring connector was engaged to a holding member on a foot band encircling the forefoot of the walking cast. Adapted to the user, the lead strap was forward of the user&#39;s body. When the walking cast was in contact with the ground, the spring was stretched and potential energy stored. During the next forward step of the ambulation cycle, the spring assisted the patient with lifting the leg and cast thereby reducing the strain on the muscles of the leg. During this portion of the ambulation cycle, the load was distributed onto the user&#39;s shoulder. In order to modify the Resilient Harness Device For A Walking Cast to a functional ambulatory leg sling, numerous modifications would be necessary. However, there exists no suggestion in this art, expressed or implied, to modify the Resilient Harness Device For A Walking Cast into a functional leg sling. Assuming the minimal necessary modifications are performed, these modifications necessitate removal of the spring, removal of one swivel eye spring connector, reversal of the remaining swivel eye spring connector to orient the releasable end at the lower end of the lead strap, incorporation of a lead strap length adjustment means, and incorporation of a pad into the body harness to improve the user&#39;s comfort and mitigate the pressure on the shoulder. However, even if these modifications were made, the single foot band would produce an inferior result when suspending the leg. The use of the single band would increase discomfort when the leg was suspended for long periods, especially for the user with only a bandage covering the foot. With only the single band encircling the forefoot, the constant pressure applied at one location would increase discomfort since all forces born by the elevated foot are distributed about the single location. Further, these modifications would render the Resilient Harness Device For A Walking Cast inoperable for its intended function. 
   Another device of the prior art is U.S. Pat. No. 5,860,944, Hoffman, Jr. (1999). Hoffman, Jr. disclosed the Back Support Apparatus that essentially included a pair of shoulder straps, a waist belt, two guide tubes, a pair of heel connectors, a pair of support lines, and a pair of coil springs integrated into each of the support lines. The Back Support Apparatus assists the user with back support as an aid in performing manual labor requiring frequent bending from the waist. Adapted to the user, each support line was engaged to a heel connector attached to the user&#39;s feet; each heel connector was configured to couple with the respective heel of the shoe on each foot. Fixedly attached to each heel connector was a connection eye similar in design to an eyebolt. The connection eye was fixedly attached to the heel connector on the upstanding heel brace with the connection eye oriented upward and in line with the attached support line. The lower end of the wire rope support line was fixedly attached by a loop formed from the wire rope passing through the connector eye and then secured to itself with a suitable clamp. As designed, the connector eye was a rigid, non-pivotal anchor for securing the support line; the opposite end of each support line was adapted to the user&#39;s shoulders through the shoulder straps. Two straps with hook and loop fastener were included on each heel connector for snugly securing the heel connector to the user&#39;s shoe. If the heel connector is integrated as a foot receiving means into an ambulatory leg sling, the patient must wear a shoe since the heel connector is configured to couple with the respective heel of the user&#39;s shoe. A cast is typically wider than a shoe, and the upstanding heel brace would interfere with the cast properly seating into the heel connector. It would be necessary to expand the width of the heel connector to accommodate the cast; however, this would make the heel connector too large to snugly fit around a user&#39;s shoe or bandaged foot and thereby produce an inferior result. Although U.S. Pat. No. 5,860,944 does not state the material composition of the heel connector, the drawings suggest a rigid material such as a metal alloy or a hard plastic. In order to be an effective foot receiving means for an ambulatory leg sling, the foot receiving means must be adjustable in size to accommodate either a cast or a bandaged foot and be flexible to enhance comfort; the heel connector described does not afford these benefits. Further, the wire rope integrated into the support line and fixedly attached by loop and clamp to the eye connector must be removed from the heel connector, and removal of the wire rope would render the heel connector inoperable for its intended function. Yet, even if these modifications were performed, the heel connector would produce an inferior result for suspending the leg because of the force distribution problems described previously when the forces are distributed about a single location on the foot. And, the heel connector would not comfortably, securely remain on the foot during extended periods of bed rest due to its hard material structure and limited means of being secured to the shoe. Thus, the heel connector would not provide a suitable foot receiving means for the ambulatory leg sling. 
   BRIEF SUMMARY OF THE INVENTION 
   In accordance with the present invention, the Breakaway Leg Sling is provided comprising: a load bearing means provided by a torso harness device equipped with a single anchor ring; a soft, flexible foot receiving means provided by a separable foot cradle device equipped with a single anchor ring; a load transfer means provided by a load strap used to engage the single anchor of the foot receiving means to the single anchor of the load bearing means; a means to provide the patient immediate use of the injured leg in order to regain balance and prevent a fall provided by the breakaway safety fastener incorporated into the length of the load strap. Integrated into the Breakaway Leg Sling, these components provide a secure, safe, ergonomic leg suspensory system for use with the walker or crutches that lifts and suspends the single leg in a rearward, elevated position during the transition of standing from a seated position. The apparatus provides ample security from weight bearing while in the motion of standing, while in the sitting motion, or during the ambulation cycle. The apparatus provides a means to break apart using the breakaway safety fastener thereby providing the patient immediate use of the injured leg to prevent a fall and regain balance in the event of a trip or other loss of balance. And, the threshold of force required to open the breakaway safety fastener is sufficiently above the load of the suspended leg to provide the patient all of the advantages of the Breakaway Leg Sling during normal, routine use without the fastener accidentally opening. Yet, the breakaway safety fastener opens immediately when a sufficient pre-determined force is exerted on the safety fastener, such as the force exerted during the initial stage of a loss of balance. For patients ranging in weight from one hundred to two hundred and fifty pounds, the target force for opening the breakaway safety fastener is approximately twenty pounds. In a rearward, elevated rest position, the load of the single leg of the patient typically ranges from six to twelve pounds in the defined weight range, which includes the weight of a cast or shoe. Thus, to disengage the breakaway safety fastener and release the injured leg, the patient must exert a force on the load strap equal only to the difference between the opening force of the breakaway safety fastener and the force exerted on the breakaway safety fastener by the mere load of the suspended, rearward at rest leg. Those skilled in the prior art of leg slings have not recognized the need or advantages associated with integration of the breakaway safety fastener into the sling assembly to prevent a potential fall. This invention solves this unrecognized problem and provides a secure means of encasing the cast, boot, or shoe with straps; the device provided for this means is the foot cradle device. Furthermore, the foot cradle device provides two complementing, integrated bands, i.e., the forefoot loop and the ankle loop. When adapted to the user&#39;s foot, both bands completely encircle the foot and ergonomically interface with the natural shape of the human foot to eliminate slippage and improve the distribution of the forces born by the foot over a larger surface area thereby enhancing the patient&#39;s comfort. In order to suspend the leg, the foot cradle device provides the anchor ring on the rearward side of the heel to engage the lower end of the load strap. The upper end of the load strap is engaged to the anchor ring on the torso harness device. Incorporated into the length of the load strap is the breakaway safety fastener. Integrated into the Breakaway Leg Sling, the torso harness device, the foot cradle device, the load strap, and the breakaway safety fastener provide many advantages for the patient. Those skilled in the art will appreciate the secure means of suspension and comfort afforded by this invention and the enhanced safety of the patient provided by the breakaway safety fastener. 
   OBJECTS AND ADVANTAGES 
   Accordingly, several objects and advantages of this invention are:
         (a) an improved and comfortable ambulatory leg sling;   (b) a device for encasing the foot that eliminates slippage about a cast, shoe, or bandaged foot;   (c) a foot cradle device that better distributes the forces born by the suspended foot;   (d) a safer means to avoid weight bearing on the sole of the foot during the ambulation cycle with the walker or crutches and, if needed, permit the patient immediate use of the injured leg to regain balance;   (e) an improved quality of life for patients during convalescence;   (f) an expedient means of preparing the Breakaway Leg Sling for use;   (g) a simple method of preparing the Breakaway Leg Sling for use from the seated position;   (h) an apparatus that lifts the leg securely, safely during the standing motion;   (i) an apparatus that does not hamper the patient during the sitting motion;   (j) a torso harness that is easily removed after sitting;   (k) a cushioned torso harness device to enhance comfort on the patient&#39;s shoulder;   (l) a comfortable means to maintain the foot cradle device on the foot for extended periods of time while sitting, resting, or sleeping thereby leaving the foot cradle device anchor in a ready-to-connect position to minimize preparation time and effort;   (m) a low manufacturing cost.       

   In addition to the objects and advantages listed herein, further objects and advantages will become apparent from a consideration of the drawings and the ensuing description. 

   
     BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING 
       FIG. 1  is a left side perspective view of a patient with the Breakaway Leg Sling suspending the left leg. 
       FIG. 2  is a rear side perspective view of the patient with the Breakaway Leg Sling suspending the left leg. 
       FIG. 3  is a front side perspective view of the preferred embodiment of the foot cradle device. 
       FIG. 4  is a rear side perspective view of the preferred embodiment of the foot cradle device. 
       FIG. 5  is a side perspective view of the preferred embodiment of the torso harness device and the preferred embodiment of the load strap. 
       FIG. 6  is an enlarged perspective view of the breakaway safety fastener in a closed position. 
       FIG. 7  is an enlarged perspective view of the breakaway safety fastener in an open position. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   Description of Figures 
   Reference is first made to FIG.  1  and  FIG. 2 , which illustrate the preferred embodiment of the invention. The Breakaway Leg Sling is comprised of three integrated assemblies consisting of the foot cradle device  20 , the load strap  90 , and the torso harness device  70 . The torso harness is the load bearing means, and the foot cradle device is the foot receiving means. The load strap is the load transfer means used to integrate the load bearing means with the foot receiving means. Opposite ends of the load strap connect to the anchor ring  32  on the foot cradle device and to the anchor ring  72  on the torso harness device, and the breakaway safety fastener  93  is incorporated into the length of the load strap  90 . As illustrated, the anchor  72  on the torso harness resides at the bottom of the torso harness loop, and the anchor  32  on the foot cradle device resides approximately along the axis of the Achilles tendon. It will be appreciated by those skilled in the art that the foot cradle device provides for ease of applying and removing, as well as a secure, customized fit. 
   Preferred Embodiment of the Foot Cradle Device 
   Referring now to FIG.  3  and  FIG. 4 , front and rear perspective views of the foot cradle device  20  are provided. As illustrated, the foot cradle device  20  is comprised of a forefoot loop  22 , an ankle loop  24 , a forefoot-connector loop  26 , a plantar strap  28 , the anchor ring  32 , and a fold-down strap  34 . A detailed description of each follows. 
   Referring to  FIG. 3 , three pieces of strap made of nylon webbing are fashioned into a loop, herein defined as the forefoot loop  22 . To make the forefoot loop  22 , a first strap, adapted to extend along the sole of the foot, is cut to length and opposite ends of the strap are secured by thread to the two double bar slides  42 A and  42 B on the side of each double bar slide incapable of adjustment. The two double bar slides  42 A and  42 B each provide one side capable of adjustment for the length of a strap; the remaining side of each double bar slide provides for fixedly attaching a strap to that end. The two straps  40 A and strap  40 B are cut to length and one end of strap  40 A is secured by thread to annular ring  38 ; one end of strap  40 B is secured by thread to annular ring  38 . The secured ends of strap  40 A and  40 B are at opposite sides of the annular ring  38 . The free end of strap  40 A passes through the adjustable end of the double bar slide  42 A; the free end of strap  40 B passes through the adjustable end of the double bar slide  42 B. When positioned on the patient&#39;s foot, the forefoot loop  22  provides the annular ring  38  residing on the top of the foot forward of the shank of the leg and the two double bar slides  42 A and  42 B integrated into the forefoot loop  22  on opposite sides of the annular ring  38 . The circumference of the forefoot loop  22  is adjustable by pulling or pushing the free ends of strap  40 A and  40 B through the adjustable end of the double bar slide  42 A and  42 B. 
   A smaller loop, herein defined as the forefoot-connector loop  26 , is attached to the annular ring  38 . To fashion the forefoot-connector loop  26 , a strap is first inserted through the ring  38 , and the terminal ends of the strap are overlapped and secured by thread. Loop  26  should be of sufficient size to permit the strap comprising the ankle loop  24  with buckle  48  to slide through easily when the ankle loop  24  is disengaged. Referring to  FIG. 4 , on the plantar side of the foot centered opposite from the position of the annular ring  38  shown in  FIG. 3  is the plantar strap  28 . As illustrated in  FIG. 4 , the first end of the plantar strap  28  is secured by thread to the forefoot loop  22  at the seam  50 . Both the annular ring  38  shown in FIG.  3  and the seam  50  shown in  FIG. 4  lie approximately along an axis parallel to an imaginary line centered and extending down the length of the foot. As illustrated in  FIG. 4 , the plantar strap  28  extends from the seam  50  to the seam  60 . At seam  60 , the fold-down strap  34  is secured by thread to the plantar strap  28 . 
   Referring to  FIG. 3 , the ankle loop  24  is fashioned from a detachable strap. The side release buckle  48 , provided with a male end and female end for closing the buckle  48 , is equipped with one adjustable end and one non-adjustable end. One end of the strap comprising the ankle loop  24  is fixedly attached to the non-adjustable end of the buckle  48 ; the opposite end of the strap passes through the adjustable end of buckle  48 . Closing the buckle  48  forms the strap into the ankle loop  24 . The end of the strap forming ankle loop  24  passing through the adjustable end of the buckle  48  provides the means of adjusting the circumference of the ankle loop strap  24  by pulling or pushing on this end of the strap. Thus, the patient may adjust the circumference of the ankle loop  24  to snugly encircle the ankle. Referring to  FIG. 4 , Integrated onto the strap forming the ankle loop  24 , residing along the length of the strap between the terminal ends, is the anchor ring  32 . The single bar slide  54  provides a means to maintain the anchor ring  32  in a stationary position on the ankle loop  24 ; yet, the anchor ring  32  is pivotal within the single bar slide  54  to a range of approximately 180 degrees. This pivotal capability of the anchor ring  32  permits the anchor ring to fold down and out of the way when the patient is wearing the foot cradle device  20  and resting the leg on a bed or similar surface. Furthermore, the patient may slide the anchor ring  32  and single bar slide  54  to alternate positions along the length of ankle loop  24 . This provides the patient a means to position the anchor  32  on the rearward side of the heel along the axis of the Achilles tendon while custom fitting the foot cradle device  20 . To place the anchor ring  32  and single bar slide  54  onto the strap, a free end of the strap comprising ankle loop  24  first passes through the single bar slide  54 , then through the D-ring  32 , and finally again through the single bar slide  54 . Thus, the anchor ring  32  is integrated with the single bar slide  54 , and the single bar slide  54  keeps the anchor ring  32  stationary unless the patient needs to adjust the position of the anchor ring  32  by sliding the anchor  32  along the length of the strap. Integration of the ankle loop  24  into the foot cradle device  20  is accomplished by inserting the strap comprising the ankle loop  24 , after releasing the buckle  48 , through the forefoot-connector loop  26 . Thus, the ankle loop  24  is detachable from the other elements of the foot cradle device; the closure of the buckle  48  forms the ankle loop  24 . The last element of the foot cradle device  20  is the fold-down strap  34 . The fold-down strap  34  is secured to the plantar strap  28  such that equal lengths of the fold-down strap  34  extend from the seam  60 . Referring to  FIG. 4 , at the first end of the fold-down strap  34  on the lateral side of the ankle, complementing hook and loop are sewn onto the strap  34  at location  58  to accommodate a fold. At the second end of the strap  34  on the medial side of the ankle, complementing hook and loop are sewn onto the strap  34  at location  56  to accommodate a second fold. To integrate the fold-down strap  34  into the foot cradle device  20 , the first end is placed underneath the ankle loop  24  on the lateral side of the ankle; the first end is folded back and attached to itself using the complementing hook and loop sewn onto the strap  34  at location  58  thereby sandwiching the enclosed portion of the ankle loop  24  in the fold. The strap  34  extends from the first fold underneath the foot to the opposite ankle on the medial side. The second end of the strap  34  is inserted underneath the ankle loop  24  on the side opposite the first fold, and the second end of the strap  34  is folded back upon itself and attached to itself using complementing hook and loop sewn at location  56  thereby sandwiching the enclosed portion of the ankle loop  24  in the second fold. As seen in  FIG. 4 , where the fold-down strap  34  crosses over the plantar strap  28  on the plantar side of the foot, strap  28  and strap  34  are fixedly attached at seam  60 . 
   Preferred Embodiment of the Load Strap 
   Again referring to  FIG. 1 , the load strap  90  provides the means to transfer the load of the suspended leg to the torso harness device  70 . As illustrated in  FIG. 5 , the load strap  90  is comprised of the pivotal snap hook  94 , an elongated strap  92 A, a shorter elongated strap  92 B, the double bar slide  96 , and the breakaway safety fastener  93 . Again referring to  FIG. 1 , one end of the load strap  90  is attached to the torso harness anchor ring  72 ; the opposite end of the load strap  90  provides the pivotal snap hook  94  to engage the anchor ring  32  on the foot cradle device  20 . Again referring to  FIG. 5 , one side of the double bar slide  96  provides a means to adjust the length of the strap passing through the double bar slide  96 ; the remaining side of the double bar slide  96  provides a non-adjustable means for fixedly attaching the strap to that end. To fashion the load strap  90 , one terminal end of the strap  92 A is fixedly attached by thread to the non-adjustable side of the double bar slide  96 . The opposite end of strap  92 A first passes through the strap-holding member of pivotal snap hook  94 . Then, the free end of strap  92 A passes through the strap-holding member  91 A located at one end of the breakaway safety fastener  93 . Then the end of strap  92 A passes through the adjustable end of the double bar slide  96 . Thus, the strap  92 A is formed into an adjustable loop, and the pivotal snap hook  94  and strap-holding member  91 A of the breakaway safety fastener  93  reside at opposite ends of the elongated, adjustable loop. A second, shorter strap  92 B passes through the torso harness anchor ring  72  and then through the strap-holding member  91 B of the breakaway safety fastener  93 ; opposite ends of the shorter strap  92 B are joined and secured by thread thus forming strap  92 B into the loop shown in FIG.  5 . Thus, the double bar slide  96  provides a means to adjust the length of the load strap  90 ; the breakaway safety fastener  93  provides a means for the patient to regain immediate use of the suspended leg, if necessary, to prevent a potential fall. During normal use, the pivotal snap hook  94  provides the means to engage the foot cradle device anchor ring  32 , shown in FIG.  4 . 
   Preferred Embodiment of the Breakaway Safety Fastener 
   As illustrated in  FIG. 5 , the breakaway safety fastener  93  is incorporated into the length of the load strap  90 . Referring to FIG.  6  and  FIG. 7 , an enlarged view of the breakaway safety fastener  93  is provided. To make the breakaway safety fastener  93 , two equal lengths of ferrous-alloy plates are used. The approximate dimensions of the metal plates  105 A and  105 B are 1 inch by ¼ inch by 5 inches in width, thickness, and length. Two cylindrical cavities of equal depth are machine milled into the metal plate  105 A; metal plate  105 B is identical to plate  105 A. As shown in FIG.  6  and  FIG. 7 , the cavities in housing member  105 A and  105 B are nearer one end of each plate than the other end; the distance from the proximal end to the nearest cavity measures approximately ¼ inch. Each cylindrical cavity is milled to an approximate depth in the thickness of each plate to permit a magnet to be recessed into each cavity; when recessed, the magnet protrudes slightly above the surface of the plate. The thickness of the wall separating the two cavities in the plate is approximately ⅛ inch as measured along an axis extending through the center of both cavities. A cylindrical rare earth magnet of a type known to the art measuring in diameter just less than the diameter of the cylindrical cavity is inserted into each of the cavities in the two plates  105 A and  105 B. The magnets are sintered neodymium iron boron disk magnets, and the north and south poles are on opposite sides and parallel to the thickness of each disk magnet. The use of the ferrous-alloy housing member for plates  105 A and  105 B precludes the need for bonding the magnets to the housing members and protects the sintered neodymium iron boron magnets from damage during closing of the fastener; the magnets remain recessed in their respective cavities during use. Alternate material embodiments of the housing members  105 A and  105 B, such as a plastic or a non-ferrous alloy material, require the magnets to be bonded or glued into their cavities. Each magnet disk measures approximately ¾ inch by ⅛ inch in diameter and thickness. All four magnets are of equal magnetic strength. In a magnetic pull test, the single disk magnet is sandwiched between two ¼ inch thick ferrous-alloy plates, and the two widest surfaces of the single disk magnet are in flush contact with the two separate metal plates. When the pull force is applied to one plate parallel to the thickness of the disk magnet and the second plate is held stationary, the force required to separate the two plates equals approximately fifteen pounds. As illustrated in  FIG. 6 , magnets  101 A and  101 B are inserted into the two cavities of the plate  105 A; magnets  103 A and  103 B are inserted into the two cavities of the plate  105 B. As illustrated in  FIG. 7 , magnet  101 A and  101 B provide opposite magnetic pole orientation relative to the plate  105 A; magnet  103 A and  103 B provide opposite magnetic pole orientation relative to the plate  105 B. This north-south orientation is illustrated in FIG.  6  and  FIG. 7  where “N” represents the north pole of the magnet and “S” represents the south pole of the magnet; the poles are parallel to the thickness of the magnet disks. Thus, the two magnets in each plate  105 A and  105 B provide one magnet with a south pole orientation and one magnet with a north pole orientation, and complementing magnets in plate  105 A and  105 B attract each other when the plates  105 A and  105 B are coupled. Each coupled magnet pair between housing member  105 A and  105 B are coaxially located and in flush contact when the breakaway safety fastener  93  is in the closed position. Since the magnets protrude slightly above the surface plane of plate  105 A and plate  105 B, only the complementing magnets contact when the breakaway safety fastener  93  is coupled. And, coupled, the two sets of coaxially located magnet pairs in housing member  105 A and  105 B provide a substantially rigid, non-pivotal fastener such that the housing members  105 A and  105 B are substantially non-pivotal with respect to one another. The strap holding member  91 A attached to the housing member  105 A is at the distal end from its recessed magnets  101 A and  101 B; the strap holding member  91 B attached to the housing member  105 B is at the distal end from its recessed magnets  103 A and  103 B. The strap holding members  91 A and  91 B each are a brass triangle ring of a type known to the art that is opened, inserted through holes drilled through the distal ends of the plates  105 A and  105 B, and again closed. The strap-holding members  91 A and  91 B provide the means of incorporating the breakaway safety fastener  93  into the length of the load strap  90 , as shown in FIG.  5 . Opening or disengaging the breakaway safety fastener  93  requires a pull force of approximately twenty pounds applied longitudinally to the breakaway safety fastener  93 . 
   An alternate embodiment of the breakaway safety fastener  93  envisions replacement of the four disk magnets with two bi-polar rectangular magnets; each rectangular magnet providing both a north and south pole parallel through the thickness of the magnet and at opposite ends on a single surface. The two housing members would require machine milling to provide complementing cavities in the two-piece housing for insertion of the recessed magnets. Coupled, opposite poles between the magnet pair would attract and provide a result similar to the preferred embodiment. Magnetic pull tests would be required to determine the correct size and strength of the magnet for this embodiment. 
   A second alternate embodiment of the breakaway safety fastener  93  contemplates the substitution of the ferrous-alloy with a non-ferrous alloy or plastic extrusion member. For example, each plate could be designed as a two-piece plastic extrusion component interlocking with snap-together pieces; the cavities for recessing the magnets could be formed into the plastic member, and an optional soft iron plate could be sandwiched between the joined pieces beneath the cavities and held stationary with plastic clips integrally formed in the plastic member. The magnets could be bonded to the iron plate or bonded to the plastic if the iron plate was not used. Other strap engaging means, such as accommodating slots in the distal ends of the fastener body, may be substituted for the strap holding member  91 A and  91 B. As in the preferred embodiment, the two finished housing members could be identical, and the magnets could be either disk or rectangular. 
   Preferred Embodiment of the Torso Harness Device 
   Referring to  FIG. 1 , the torso harness device  70  is the load bearing means. As illustrated in  FIG. 5 , the torso harness device includes both a front strap  74  and a rear strap  76 . Other elements of the torso harness include a pad  78 , a double bar slide  80 , the single anchor ring  72 , and a pivotal snap hook  82 . As illustrated in  FIG. 1 , the pad  78  attached to strap  74  crosses over the shoulder on the side opposite of the suspended leg and extends onto the patient&#39;s front and rear torso areas. The front strap  74  and the rear strap  76  are attached to the anchor ring  72 ; anchor ring  72  resides at the bottom of the loop. Referring to  FIG. 5 , the elongated pad  78  is made of foam rubber, cotton wadding, or any other suitable type of padding material known to the art, and the foam rubber is encased with a fabric. As illustrated, strap  74  and strap  76  extend from opposite ends of the two narrowest sides of pad  78 ; the straps  74  and  76  are made of nylon webbing or any other suitable material. One end of the front strap  74  is attached to the lower end of the pad  78 . The strap  74  extends around the side of the patient and is engaged to the torso harness anchor  72 . The rear strap  76  extends from the upper end of the pad  78 , diagonally across the patient&#39;s back, and is engaged to the anchor  72 . As illustrated in  FIG. 1 , the anchor  72  is at the bottom of the loop formed when the terminal ends of the front strap  74  and the rear strap  76  are engaged to the anchor  72 . Again referring to  FIG. 5 , at the two terminal ends of the pad  78  where the front strap  74  and the rear strap  76  are sewn to the pad  78 , the fabric of pad  78  is lapped over the ends of each strap. Each strap is then secured by thread to the fabric. Each seam is sandwiched between two pieces of like leather herein defined as seam covers  84 A and  84 B. The seam covers  84 A and  84 B provide additional strength and reinforcement for each seam. The two like pieces of  84 A and the two like pieces of  84 B are stitched together wherein the stitching passes through the first piece of leather, through the strap and the fabric, and through the second piece of leather. To provide the rear strap  76  with a means to adjust the length, the double bar slide  80  is fashioned into the length of the strap  76 . 
   Description of Operation 
   Referring to  FIG. 1 , the Breakaway Leg Sling of the instant invention is comprised, in sequential order, of the foot cradle device  20 , the load strap  90 , the breakaway safety fastener  93 , and the torso harness device  70 . As illustrated in  FIG. 1 , the secure holding members, defined as the anchors  72  and  32 , are provided on both the torso harness device and the foot cradle device. The load strap  90  provides the load transfer means wherein the opposite ends of the load strap are engaged to the anchor  72  and the anchor  32 . Integrated into the Breakaway Leg Sling, the foot cradle device  20 , the load strap  90 , the breakaway safety fastener  93  and the torso harness device  70  assist the patient with an effective, expedient, secure, and safe apparatus for weight avoidance on the suspended leg while using the walker or crutches. 
   The load strap  90  and the foot cradle device  20  are detachable from each other. The torso harness device provides the anchor ring  72 , and the foot cradle device provides the anchor ring  32 . Opposite ends of the load strap  90  are engaged to the anchor ring  32  on the foot cradle device  20  and the anchor ring  72  on the torso harness device  70 . The breakaway safety fastener  93  is incorporated into the length of the load strap  90 . The pivotal snap hook  94  attached to the lower end of the load strap  90  provides the means to engage or disengage the load strap to the anchor ring  32  during routine use. The anchor ring  32  is secure and fastened to the foot cradle device and positioned on the rearward side of the heel along the axis of the Achilles tendon. When the foot is suspended and elevated in a rearward position, the anchor ring  32  is at the highest point of elevation of the suspended foot. And, the foot cradle device may be left on the foot for extended periods of time, after removing the torso harness and load strap, thereby leaving the anchor ring  32  in the ready-to-connect position. 
   Referring to  FIG. 3 , the design of the foot cradle device  20  is such that, after custom sizing to fit the foot, the foot cradle device may be removed from the foot by releasing the single buckle  48  and replaced by closing the single buckle  48  without resizing the forefoot loop  22  or the ankle loop  24 . When the patient removes the foot cradle device, the buckle  48  is released, and the forefoot loop  22  is slipped off of the foot. The strap of the ankle loop  24  is left in position passing through the forefoot-connector loop  26 . To return the foot cradle device to the foot, the forefoot loop  22  is slipped onto the forefoot and into position. The medial side of the fold-down strap  34  is temporarily disengaged, and the buckle  48  on the ankle loop  24  is fastened. The fold-down strap  34  is pulled taunt and fastened again. Thus, removal or replacement is accomplished in a matter of seconds thereby providing the patient a means to easily remove the foot cradle device to accommodate usage of a bandage or cast protector while bathing. 
   Referring to  FIG. 3 , initially, the patient must customize the fit of the foot cradle device. The forefoot loop  22  is customized to fit the patient with the adjustable strap ends  40 A and  40 B passing through the adjustable ends of double bar slides  42 A and  42 B. To position the forefoot loop  22  on the patient, the toes are first inserted through the forefoot loop  22 . The annular ring  38  integrated into the forefoot loop  22  is positioned on the top center of the forefoot, and the forefoot loop  22  is pulled onto the forefoot and brought to rest just forward of the shank of the leg. The forefoot loop  22  should be adjusted to fit comfortably snug in this position. Next, the patient adjusts the length of the strap provided for the ankle loop  24  at the adjustable end of the buckle  48  in order to adjust the circumference of the ankle loop  24 ; the ankle loop  24  is equipped with the buckle  48  for closing the strap into the ankle loop  24 . To position the ankle loop  24 , the patient opens buckle  48  and pushes a free end of the strap comprising the ankle loop  24  through the forefoot-connector loop  26 . The male and female portions of the buckle  48  are closed, and the ankle loop  24  is now positioned about the ankle. The forefoot-connector loop  26  and the fold-down strap  34  provide the means for integrating the forefoot loop  22  and ankle loop  24 , and the complementing comfortably snug positions of the forefoot loop  22 , the ankle loop  24 , and the fold-down strap  34  eliminate slippage of the foot cradle device along the foot or leg and improve the distribution of the forces born by the foot while in the suspended state. Since the ankle loop  24  passes through the forefoot-connector loop  26  but is not fixedly sewn to other elements of the foot cradle device  20 , the buckle  48  remains positional about the ankle. Positioned correctly, the buckle  48  will reside on the medial side of the ankle to provide the patient easy access. The patient will appreciate this ergonomic feature since the buckle  48  is much easier to access on the medial side of the ankle. In addition, the positional capability of buckle  48  allows the manufacture of a single foot cradle device for use with either the right or the left foot. Referring to  FIG. 4 , while customizing the fit, the patient slides the anchor ring  32  incorporated into the single bar slide  54  to its functional position on the rearward portion of the heel along the axis of the Achilles tendon. 
   The fold-down strap  34  is the final strap adjustment on the foot cradle device  20 . To position the fold-down strap  34 , one end of the strap  34  is placed underneath the ankle loop  24  on the lateral side of the ankle; this end of the fold-down strap  34  is then folded down and attached to itself with the complementing hook and loop sewn onto the fold-down strap  34  at location  58 . The fold-down strap  34  extends from the ankle on the lateral side underneath the foot and back up to the ankle on the medial side. The second end of the fold-down strap  34  is then placed underneath the ankle loop  24  on the medial side of the ankle. The second end is folded and attached to itself with the complementing hook and loop sewn onto the fold-down strap  34  at location  56 . The ankle loop  24  is thereby sandwiched into the folds of the fold-down strap  34  on both the lateral and medial sides of the ankle. The snug position of the fold-down strap  34  pulls downward on the ankle loop  24  and keeps the ankle loop  24  from slipping along the shank of the leg. 
   Referring to  FIG. 5 , the torso harness device also requires initial adjustment to best fit the patient. The torso harness device was fashioned into the loop by engaging the strap  74  and the strap  76  to the anchor ring  72 . The desired circumference of the loop formed by the straps  74  and  76  is obtained using the double bar slide  80 . Referring to  FIG. 1 , the patient places the head through the torso harness loop and the loop depends from the shoulder on the side opposite of the suspended leg; the load strap drops into position naturally. The pad  78  extends over the top of the shoulder onto the front and rear areas of the patient&#39;s torso. The anchor ring  72  hangs alongside the hip on the side of the leg to be suspended, and the straps  74  and  76  cross diagonally the front and rear sides of the torso. At the lower end of the load strap  90  is the pivotal snap hook  94  used to engage the load strap to the anchor  32 . The double bar slide  96  is provided to adjust the length of the load strap  90  to accommodate differences in height or change the angle of elevation of the suspended leg. 
   Referring to  FIG. 1 , the patient places the torso harness device  70  in place as described from the seated position. The patient now engages the pivotal snap hook  94  on the lower end of the load strap  90  to the anchor ring  32 . The patient stands on the good leg with the assistance of the walker or crutches, and the natural motion of standing pulls the leg securely in a rearward, elevated position. A more comfortable distribution of the load is achieved by using the muscles of the suspended leg to lift the leg slightly upward thereby relaxing the tension in the torso harness device  70 . With the tension in the torso harness temporarily relieved, the patient grasps the pad  78  on the front torso and rotates the pad slightly downward about its axis. This motion repositions the torso harness anchor ring  72  more rearward and behind the buttock and improves the load distribution, and the comfortable distribution of the load is achieved. The suspended leg is now fully relaxed, and the patient is ready for the ambulation cycle. 
   Following the custom sizing, the patient may leave the foot encased by the foot cradle device  20  without hampering comfort. Wearing the foot cradle device leaves the anchor ring  32  in the ready-to-connect position and shortens preparation time before ambulation. The torso harness device  70 , with the load strap  90  attached to the anchor ring  72 , will generally be removed from the patient&#39;s body whenever the patient is sitting or lying down. 
   To assure security from weight bearing during the sitting motion, the patient first prepares to sit with the patient&#39;s back facing the chair or sitting surface. Then, while standing with the aid of the walker or crutches, the patient lifts the suspended leg slightly upward with the muscles of the leg thereby relaxing the tension in the torso harness device  70 . With the tension relaxed, the patient can easily move the suspended leg forward of the body. The torso harness loop easily turns about its axis, and the torso harness anchor ring  72  moves forward alongside the hip. The load strap  90 , still engaged to the anchors  72  and  32 , limits the arc of the swing and prevents the foot from contacting the ground. With the leg now forward of the vertical line of the body, the patient comfortably, safely sits. 
   The use of the Breakaway Leg Sling during the ambulation cycle is simple. With the leg held in its suspended state and the load distribution comfortably adjusted using the method and manner described, the patient leans slightly forward from the waist. While in this position, the patient transfers the weight of the body into the hands while gripping the handles of the walker or crutches. With the weight of the body transferred into the handles, the patient lifts the good leg, and the good leg swings forward. Balance is facilitated during this motion because the load of the suspended leg is distributed into the upper central torso of the patient. With slippage of the foot receiving means eliminated, the Breakaway Leg Sling provides the patient with security from weight bearing during ambulation. 
   The breakaway safety fastener  93  incorporated into the length of the load strap  90  remains in a closed position during the patient&#39;s normal use of the Breakaway Leg Sling. The patient uses the pivotal snap hook  94  to engage or disengage the anchor ring  32  for suspending or releasing the leg. In the event the patient loses balance while using the walker or crutches, the breakaway safety fastener  93  provides the patient immediate use of the suspended leg for regaining balance. Thus, the released leg may be used and placed on the ground if necessary, and this action facilitates the patient&#39;s ability to regain balance and avoid a potential fall. This unique safety fastener requires no adjustment before use. The force exerted on the closed fastener required to open the fastener and release the suspended leg is approximately twenty pounds. For the patient ranging in weight from one hundred to two hundred and fifty pounds, this force is easily obtained. It is contemplated that patients outside of this weight range may require a breakaway safety fastener  93  opening at a different target force, but construction of a safety fastener to accommodate the patients outside of the defined weight range is easily accomplished by incorporation of weaker or stronger magnets into housing body of the safety fastener. In the event that the breakaway safety fastener  93  opens to release the suspended leg, the patient restores the breakaway safety fastener  93  to its functional, closed position by bringing the two separated parts of the safety fastener housing into close proximity; the magnet orientations are such that the two separate parts of the fastener housing will align and snap closed. This is accomplished in a matter of seconds, and the patient is then able to immediately resume use of the Breakaway Leg Sling after restoring the breakaway safety fastener  93  to the closed position. 
   Scope and Ramifications 
   It will be apparent to those skilled in the art that various modifications and variations can be made into the system and method of the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover these modifications and variations provided they come within the scope of the appended claims and their equivalents. Several alternate embodiments of the ambulatory sling apparatus were identified in the parent application and others contemplated include substitution of different types of strap material such as nylon, leather, or the like known to the art, or substitution of different types of web strap adjustment members or holding members such as web slides, web strap locks, pivotal snap hooks, snap hooks, side release buckles, center release buckles, and the like known to the art, or substitution of different shapes of rings such as D shape rings, triangle rings, annular rings, and the like known to the art, or substitution of different types of material composition for the adjustment members, the holding members, and the rings such as plastic, metal, or the like known to the art, or substitution of fewer but stronger magnets into the fastener housing to achieve the benefits of the breakaway safety fastener, or substitution of different sized or different shaped magnets to achieve the benefits of the breakaway safety fastener, or substitution of bi-polar magnets for the conventional pole magnets to achieve the benefits of the breakaway safety fastener.

Technology Category: 1