A carrier for retaining a plurality of implants each comprising a structurally encoded pin, the structurally encoded pin having a shape or surface characteristics discernable by an imaging modality such as x-ray, fluoroscopy, computed tomography, electromagnetic radiation, ultrasound, visible light, UV light, magnetic resonance imaging, positron emission tomography and neutron imaging, from outside the carrier, the shape or surface characteristics representing structurally encoded data. The invention further discloses a carrier for viewing a plurality of implants, and associated reading systems for reading a plurality of implants. Finally, the invention discloses methods for reading a plurality of implantable devices retained within a carrier.

An implant and method for manufacturing an implant comprising an implant body defining a longitudinal axis and a structurally encoded pin contained within the implant body and aligned substantially along the longitudinal axis, the structurally encoded pin having a shape or surface characteristics discernable by an imaging modality such as x-ray, fluoroscopy, computed tomography, electromagnetic radiation, ultrasound, visible light, UV light, magnetic resonance imaging, positron emission tomography and neutron imaging, from outside the implant body, the shape or surface characteristics representing structurally encoded data. The structurally encoded pin is encoded via an electric discharge machining process.

A spinal implant device identifiable after implantation comprises an outer cage member and an implant body. The implant body is disposed between a first vertebra end and a second vertebra end of the outer cage and defines a plurality of planes. Each of the planes comprises separately readable indicia such that the indicia are discernible by at least one of x-ray, fluoroscopy, computed tomography, electromagnetic radiation, ultrasound, or magnetic resonance imaging.

A plasmonic pixel structure, comprising: a substrate; a plurality of nano-scale structures each comprising conducting and dielectric components, whereby the nano-scale structures are configured to act as nano-antennas. The nano-scale structures 5 have resonant frequencies that depend on the conducting component and sizes of the nano-scale structures. The conducting component and the sizes of the nano-scale structures are selected according to a wavelength component or components of incident light desired to be reflected or transmitted by the nano-scale structures, and the conducting component and the sizes of the nano-scale structures are selected 10 such that the nano-scale structures have respective resonant frequencies corresponding to a colour scheme.

An implant containing a structurally encoded region, the implant comprising an implant body defining adjacent first and second encoded regions, the first encoded region comprising a first series of shaped inclusions in a first pattern of relatively differing opacity figures, and the second encoded region comprising a second series of shaped inclusions in a second pattern of relatively differing opacity figures, the first and second encoded regions being disposed such that, when the first encoded region and second encoded regions are viewed by reading illumination from a position wherein the first pattern and second pattern overlap, a third pattern is revealed by the reading illumination, the third pattern being different than the first and second patterns, and comprising shape or surface characteristics representing structurally encoded data. The invention further comprises systems and methods of manufacturing, using and reading the same.

Disclosed is a method for associating a marking with an object, including the following steps: identifying the position of at least two different elements of the marking in relation to the marking and/or the object; andmeasuring a relative distance between at least two identified elements; thenrecording in a database the position of at least two identified elements, and the relative distance between the identified elements so that the position of two identified elements is correlated with the measurement relating to their distance.

A method of waste separation includes irradiating the waste by a source of radiation, capturing an image of the waste when irradiated by the source of radiation; where an item in the waste is provided with a pattern, the pattern being provided in or on a surface of the item, the pattern forming a repetition of dots, a code being stored in a sequence of adjacent ones of the dots, processing the image to detect the pattern; deriving the code from the sequence of adjacent ones of the dots of the pattern; separating in accordance with the code the item the pattern from the waste. The pattern may be a relief pattern. The relief pattern may comprise a pattern of bumps and recesses. The pattern, such as in a form of a relief, may also be applied to identify the item.

Techniques for integrating a machine-readable matrix with a component of a mechanical structure using three-dimensional (3-D) printing are disclosed. Such techniques include generating at least one data model representing the component, and projecting a matrix pattern identifying one or more features of the component onto a selected surface portion of the component to produce a modified data model for use as an input to a 3-D printer.

A method of waste separation includes irradiating the waste by a source of radiation, capturing an image of the waste when irradiated by the source of radiation; where an item in the waste is provided with a pattern, the pattern being provided in or on a surface of the item, the pattern forming a repetition of dots, a code being stored in a sequence of adjacent ones of the dots, processing the image to detect the pattern; deriving the code from the sequence of adjacent ones of the dots of the pattern; separating in accordance with the code the item the pattern from the waste. The pattern may be a relief pattern. The relief pattern may comprise a pattern of bumps and recesses. The pattern, such as in a form of a relief, may also be applied to identify the item.

Techniques for integrating a machine-readable matrix with a component of a mechanical structure using three-dimensional (3-D) printing are disclosed. Such techniques include generating at least one data model representing the component, and projecting a matrix pattern identifying one or more features of the component onto a selected surface portion of the component to produce a modified data model for use as an input to a 3-D printer.