A new minimally invasive surgical approach is proposed that contemplates a method and apparatus for tightening lax skin without visible scarring via a device in various surgical procedures such as plastic surgery procedures. In some embodiments, the device is a single use disposable instrument. This approach circumvents surgically related scarring and the clinical variability of electromagnetic heating of the skin and performs small multiple pixilated resections of skin as a minimally invasive alternative to large Plastic surgical resections of skin. This approach can also be employed in areas of the body that are currently off limits to plastic surgery due to the visibility of the surgical scar. In addition, the approach can perform a skin grafting operation by harvesting the transected incisions of skin from a tissue site of a donor onto a skin defect site of a recipient with reduced scarring of the patient's donor site.

Exemplary embodiments of the present disclosure provide method and apparatus for effecting (e.g., lightening) an appearance of skin by cooling or freezing small separated surface regions of the skin to produce regions of local hypopigmentation. The width of the regions can be, for example, smaller than about 1 mm or 0.5 mm, and a distance between these frozen regions can be greater than about 3 times the width of the regions. An exemplary apparatus can be provided that includes a plurality of spatially-separated thermally conductive arrangements that can be affixed or otherwise coupled to a base. For example, the conductive arrangements can be regions of conductive material provided in or proximal to a thermal insulator, or thermally conductive protrusions affixed to the base. The conductive arrangements can be cooled and then contacted with the skin surface to produce the small regions of hypopigmentation.

A method of producing an array of sharp tips including a biocompatible coating, wherein the biocompatible coating is thicker at a sharp end of the sharp tips than at a broader section of the sharp tips, the method including providing an array of sharp tips, and coating the sharp end of the sharp tips differentially from coating the broader section of the sharp tips. A method of treating skin including producing a hollow in the skin by heating and mechanically compressing epidermis while retaining a covering of stratum corneum. A method of treating tissue including heating a tip to a temperature suitable for producing a crater in the tissue, advancing the tip toward the tissue, detecting when the tip comes into contact with the tissue by detecting a change in mechanical resistance to the advancing, and measuring the mechanical resistance to the advancing. Related apparatus and methods are also described.

The present invention is directed to improved systems, devices, and methods for delivery of a cryogen to the skin of a patient for skin treatment. A cryospray device configured to deliver a cryogen to a patient's skin can include an applicator, a supply channel, and a nozzle assembly. The applicator can include a head portion, and the supply channel can extend through at least a portion of the head portion. The nozzle assembly can be coupled to the head portion and can be fluidly coupled to the supply channel. The nozzle assembly can include a linear array of orifices that are configured to direct a planar spray of the cryogen to cool an area of a skin tissue of the patient in a linear cooling treatment.

The invention relates to a wound cleansing device comprising a number of strand-shaped cleansing elements, characterized in that the cleansing quotient R=(E*F)/l of at least some cleansing elements is 0.05 N/mm or larger, particularly 0.1 N/mm or larger, preferably 1 N/mm or larger, particularly preferably 10 N/mm or larger and smaller than 1000 N/mm, preferably less than 500 N/mm, in particular 100 N/mm or smaller, wherein E denotes the modulus of elasticity of the material of which the cleansing elements are made, F denotes the average cross-sectional area of the cleansing elements in a direction perpendicular to the strand axis, and l denotes the effective length of the cleansing elements.

Systems and methods for assembling a plurality of tissue grafts are provided. A method includes harvesting the plurality of micro tissue grafts from a donor site, arranging the plurality of micro tissue grafts in a desired orientation, forming a tissue construct containing the plurality of micro tissue grafts arranged in the desired orientation, and applying the tissue construct to a recipient site.

Systems and methods for assembling a plurality of tissue grafts are provided. A system includes a pick and place unit, a transfer tool, and a control unit. The pick and place unit includes a moveable arm and the transfer tool is coupled to a distal end of the arm. The control unit is configured to control the moveable arm to move the transfer tool to a donor site and a graft construction site. The control unit is further configured to control the transfer tool to harvest the micro tissue grafts from the donor site and arrange the micro tissue grafts into a supportive matrix to form a custom graft.

A double edged blade assembly includes a double edged blade. Additionally, the double edged blade assembly includes two blade grips coupled to the double edged blade. The two blade grips are coupled to the double edged blade at opposite ends of the double edged blade.

A microneedling system may reciprocate a plurality of microneedles disposed on a handpiece into the skin of a patient. The microneedles and/or electrode plates may deliver RF energy to the patient for inducing collagen coagulation and regeneration. An interrogative modality such as ultrasound may combined into the microneedling handpiece or used as a separate instrument to interrogate the skin and identify or measure the thicknesses of constituent layers. The data obtained from the interrogative modality may be displayed and can be used to automatically adjust operating parameters of the microneedling device, including the penetration depth of the needles, the pulse duration, and/or the power level of the RF energy to optimize the treatment for the specific patient and/or condition being treated. The microneedling system may recall the skin measurements for distinct sectors of the skin which are expected to have different properties.

In combined methods for treating a patient using time-varying magnetic field, treatment methods combine various approaches for aesthetic treatment. A magnetic field generating device is placed proximate to a body region of the patient. The magnetic field generating device generates a time-varying magnetic field with a magnetic flux density in a range of 0.5 to 7 Tesla. The time-varying magnetic field is applied to the body region of the patient in order to cause a contraction of a muscle within the body region. A second therapy may be used by applying one or more of optical waves, radio frequency waves, mechanical waves, negative or positive pressure or heat to the body region of the patient.