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Rim anchoring systems for flexible surgical implants for replacing cartilage

Inactive Publication Date: 2013-07-25
MANSMANN KEVIN A
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

The patent text describes improved designs for flexible implants that can replace damaged cartilage in joints. The implant is made of a hydrophilic polymer that is shaped like a damaged cartilage segment and has an enlarged edge that fits into a groove in the bone surface. This creates a secure fit that can withstand peak loads. A stabilizing ring made of shape-memory or super-elastic material can be embedded within the enlarged edge of the implant to allow for flexing and insertion into a joint. After the implant settles into the bone groove, it emerges from the insertion tube and returns to its normal shape to perform a reinforcing and stabilizing role.

Problems solved by technology

Accordingly, nitinol devices will not make self-directed transitions into shorter or longer lengths, or other different shapes, when chilled or heated.
However, a typical rubber band that has a substantial length will not attempt to return to a certain specific shape.
However, additional research by the Applicant has identified an important obstacle to such use of nitinol alloys, in implants that will remain in a patient's body for an extended period of time.
That obstacle involves a risk of corrosion, which is believed to arise primarily in areas where nickel atoms cluster together in “nickel-enriched” clusters or “pockets” that can have molecular structures and / or “lattice ratios” such as Ni3Ti.
As a result, during the manufacture of a nitinol component, if small pockets of material are formed that have nickel content greater than 50%, the nickel atoms in those pockets can be leached out, over a span of months or years, in ways that can lead to corrosion, cavities, and structural weakness.
Those types of long-term testing requirements could lead to severe problems and delays, especially if the main goal of such long-term clinical trials would be to ensure that a certain type of component material will not slowly corrode, over a span of a decade or more, in a mammalian joint.

Method used

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  • Rim anchoring systems for flexible surgical implants for replacing cartilage
  • Rim anchoring systems for flexible surgical implants for replacing cartilage
  • Rim anchoring systems for flexible surgical implants for replacing cartilage

Examples

Experimental program
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Embodiment Construction

[0049]As briefly summarized above, a surgical implant 100, designed for replacing a relatively large segment of hyaline cartilage in a synovial joint such as a knee, shoulder, hip, etc.) is illustrated in FIGS. 1-3. Scaled-down implants with the same structures described herein, but with smaller diameters and thicknesses (and with only one or two anchoring screws, pins, or other components, which also can be smaller) also can be created for replacing hyaline cartilage in smaller joints, such as in thumbs, fingers, wrists, etc.

[0050]For simplicity of illustration, implant 100 is shown as having a generally round and flat shape. In actual use, any such implant designed for a large joint should have a molded and shaped articulating surface that will closely emulate the size and shape of the cartilage segment that is being replaced by the implant. The sizes and shapes of such cartilage surfaces (such as, within a knee joint, the medial and lateral femoral runners, the tibial plateau, an...

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PUM

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Abstract

Flexible cartilage-replacing implants are disclosed that use either or both of (1) enlarged peripheral rim components, and / or (2) elongated flexible reinforcing members that are embedded around the peripheral edge of an implant device. These types of anchoring devices, especially when used in combination, can provide flexible implants that can be implanted arthroscopically into synovial joints, for complete replacement of damaged cartilage segments.

Description

RELATED APPLICATION[0001]This application is a continuation-in-part of U.S. utility application Ser. No. 13 / 355,276, which in turn claimed priority, under 35 USC 119, based on provisional application 61 / 434,145, filed on Jan. 19, 2011.BACKGROUND OF THE INVENTION[0002]This invention is in the field of surgical implants, and relates to devices and methods for repairing hyaline or meniscal cartilage in joints such as knees, hips, fingers, shoulders, etc.[0003]In joints that are lubricated by synovial fluid, hyaline and meniscal cartilage segments provide smooth, slippery, lubricated (or lubricious) surfaces that enable bones to move and slide, relative to other bones. “Hyaline” cartilage refers to the types of cartilage segments that are affixed, in relatively thin layers, directly to bone surfaces (often called condyles). Background information on hyaline cartilage, and on surgical implants for replacing injured or diseased hyaline cartilage, is available from various sources, includi...

Claims

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Application Information

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IPC IPC(8): A61F2/08
CPCA61F2/3872A61F2230/0093A61F2/30756A61F2/30767A61F2/3094A61F2/30965A61F2/32A61F2/389A61F2/40A61F2/4637A61F2002/2821A61F2002/30113A61F2002/30115A61F2002/30204A61F2002/30225A61F2002/30299A61F2002/30354A61F2002/30459A61F2002/30461A61F2002/30499A61F2002/305A61F2002/30604A61F2002/30738A61F2002/3085A61F2002/30878A61F2002/30892A61F2002/4635A61F2220/0025A61F2220/0033A61F2220/0066A61F2220/0075A61F2230/0006A61F2230/0008A61F2230/0065A61F2230/0069A61F2210/0019A61F2002/302A61F2002/30495A61F2220/0016A61F2002/30757
Inventor MANSMANN, KEVIN A.
Owner MANSMANN KEVIN A
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