A skin imaging and diagnostic method and apparatus comprising, a frame, configured to circumscribe a target tissue on the skin of a patient. An electro-optics unit of the apparatus comprising: an illuminator assembly comprising illuminating elements, configured to provide illumination light on the target tissue; an imaging optics assembly; and an image sensor assembly, comprising an image sensor, wherein the imaging optics assembly is configured to collect backscattered said illumination light from the target tissue and focus the collected backscattered illumination light on the image sensor; and the image sensor is disposed to consequently sense an image of the target tissue. A controller configured to activate illuminating elements and to capture each image from the image sensor.

A hair cutting device according to the present disclosure comprises an optical waveguide. The optical waveguide comprises a light irradiator. The light irradiator irradiates hair protruding from the skin with light to cut the hair. The refractive index of the light irradiator is smaller than the refractive index of the surface of the skin. As a result, options such as the material of the optical waveguide and the like can be increased. Furthermore, for example, when the skin is appropriately irradiated with light from the light irradiator, an action on the skin such as sterilization or activation can also be expected.

A transfer device for a living organism for placing an object in a living organism comprises a plurality of movable units. Each movable unit comprises one or more needles extending in a first direction. Each needle has a cylindrical shape capable of storing the object therein. Each movable unit is movable in the first direction.

Methods and systems are provided useful in various procedures, including hair harvesting and implantation, and further including computer-implemented and/or robotic hair transplantation. Methodologies are provided which enable a tool, such as a hair harvesting or a hair implantation tool, to proceed at least under a partial computer control in a selected direction of travel along a donor or recipient area of the patient, as well as changing direction of travel based on desired harvesting and/or implantation criteria.

The present invention provides an artificial hair and a method for producing same. The method for producing an artificial hair according to the present invention comprises: a step of mixing polyamide 6 powder and a master batch at a predetermined weight ratio; a step of drawing an artificial hair from the mixture; a step of forming a loop part by knotting a distal end of the drawn artificial hair; a step of cutting the distal end of the artificial hair, leaving just 1-1.5 mm from the knotted part of the loop part; a step of trimming the artificial hair to a predetermined length after the cutting; and a step of bundling a plurality of the trimmed artificial hair.

A hair implant suitable for subcutaneous implantation is provided having an anchor comprising an anchor body, and at least one collagen receiving structure selected from the group consisting of at least one tunnel disposed through the anchor body and an external surface feature of the anchor body. The anchor further comprises at least one hair strand projecting from a distal end of the anchor body, wherein the at least one collagen receiving structure is configured to support collagen ligature growth after subcutaneous implantation of the hair implant so as to anchor the anchor to a hair implant recipient, and the collagen receiving structure is free of hair.

An apparatus for automatically separating hair follicles includes a follicle separating unit configured to cut a skin tissue of a scalp cut from a back of a head of an alopecic patient in units of follicles and to classify follicles by a number of hairs included in each follicle in an incisional hair transplant or to classify follicles each directly extracted from the back of the head of the alopecic patient by the number of hairs included in each follicle in a non-incisional hair transplant, and a follicle separation control unit configured to control an operation of the follicle separating unit.

Systems, instruments, and methods for minimally invasive procedures including one or more of fractional resection, fractional lipectomy, fractional skin grafting, and/or fractional scar revision are described. Embodiments include instrumentation comprising a scalpet assembly coupled to a carrier, and the scalpet assembly includes a scalpet array. The scalpet array includes one or more scalpets configured for fractional resection, fractional lipectomy, fractional skin grafting, and/or fractional scar revision. The system includes a vacuum component coupled to the scalpet assembly and configured to evacuate tissue from the a site. The carrier is configured to control application of a rotational force and/or a vacuum force to the scalpet assembly.

Systems, instruments, and methods are described in which an apparatus comprises a housing including a scalpet device. The scalpet device includes a scalpet array that includes scalpets arranged in a pattern. The scalpets are deployable from the housing to generate incised skin pixels at a target site. The housing is positioned and the scalpet array is deployed into tissue at the target site. Incised skin pixels are generated when the target site is a donor site, and skin defects are generated when the target site is a recipient site. The incised skin pixels are harvested.

The invention relates to an automated system for performing hair restoration, which comprises automated harvest means, comprising a harvesting needle mechanism and a temporal storage means for harvested follicles; automated transplanting means, comprising a transplanting needle mechanism and a temporal storage means from which harvested follicles are extracted for transplantations; displacement means, onto which one of the automated harvest means or one of the automated transplanting means are movably connected for being displaced to desirable harvest or transplantation target points of a patient head; image acquisition means for acquiring images of a patient's scalp; mechanical support means for supporting and stabilizing the patient and particularly the patient's head during the restoration procedure; a control module, comprising suitable data processing and storage hardware and software configured to receive and process images acquired by the two or more image acquisition by image processing algorithms, map the initial patient's hair distribution, identify qualifying candidate follicles for transplantation, and finally to generate an optimized harvest and transplantation plan considering aesthetic, efficiency and safety optimization parameters. The control module is further configured to operate the at least one automated harvest means, the at least one automated transplanting means and the at least one displacement means to harvest and to transplant hair follicles in accordance with the generated optimized harvest and transplantation plan.