Abstract: Systems for treating a subject's tissue can include a thermally conductive cup, a sealing member, and/or a liner assembly. The systems can include an applicator capable of being reconfigured for a particular treatment site. Components of the applicator can be replaced to achieve a desired configuration. The replaceable components can include contoured heads, liners, and/or sensors. The applicator can draw a vacuum to install various components and/or draw tissue into the applicator. The applicator can cool and/or heat the tissue to affect targeted tissue.

Abstract: A method and apparatus in accordance with a particular embodiment of the present invention includes applying adhesive onto skin of a human subject. An applicator is then brought into contact with the adhesive such the adhesive is disposed between the applicator and the subject's skin. The applicator is activated to cool a tissue region via the subject's skin, via the heat-transfer surface of the applicator, and via the adhesive. While the tissue region cools, the adhesive also cools, thereby reversibly strengthening adhesion between the subject's skin and the heat-transfer surface and forming a strong bond therebetween. The strengthened adhesion inhibits any movement of the applicator relative to the skin. After cooling the tissue region, the adhesive is warmed, thereby weakening the adhesion which allows the heat-transfer surface of the applicator to be easily separated from the skin.

Abstract: Treatment systems, methods, and apparatuses for improving the appearance of skin and other treatments are described. Aspects of the technology are directed to improving the appearance of skin by reducing a vascular structure. A non-invasive cooling device can cover and cool the vascular structure to affect the blood vessels of the vascular structure.

Abstract: Treatment systems, methods, and apparatuses for improving the appearance of skin and other treatments are described. Aspects of the technology are directed to improving the appearance of skin by transcutaneously cooling and affecting nerve tissue so as to inhibit facial muscular contractions and thereby reduce dynamic wrinkling. A non-invasive nerve cooling device can be applied to the subject's head to attenuate nervous system signals to facial muscles.

Abstract: Treatment systems, methods, and apparatuses for treating acne, hyperhidrosis, and other skin conditions are described. Aspects of the technology can include cooling a surface of a patient's skin and detecting changes in the tissue. The tissue can be cooled a sufficient length of time and to a temperature low enough to affect glands or other targeted structures in the skin.

Abstract: Systems and methods that enable tissue cooling and delivery of energy for altering tissue are described herein. Aspects of the disclosure are directed to, for example, heating tissue at treatment zones to ablate, denature, reorganize, coagulate, or otherwise alter the tissue to affect the cosmetic appearance of the patient. The method can include, for example, removing heat from the target region of the human subject before, during, and/or after energy delivery to cool tissue to a temperature below normal body temperature to inhibit pain.

Abstract: Systems for treating a subject's tissue can include a thermally conductive cup, a tissue-receiving cavity, and a vacuum port. The vacuum port is in fluid communication with the tissue-receiving cavity to provide a vacuum for drawing the submental tissue, or other targeted tissue, into the tissue-receiving cavity. A thermal device can cool and/or heat the conductive cup such that the conductive cup non-invasively controls the temperature of subcutaneous lipid-rich cells in the tissue. A restraint apparatus can hold a the conductive cup in thermal contact with the target region.

Abstract: Treatment systems, methods, and apparatuses for improving the appearance of skin or other target regions are described. Aspects of the technology are directed to improving the appearance of skin by tightening the skin, improving skin tone or texture, eliminating or reducing wrinkles, increasing skin smoothness, or improving the appearance sites with cellulite. Treatments can include cooling a surface of a patient's skin and detecting freezing in the cooled skin. The tissue can be cooled after the freeze event is detected so to maintain the frozen state of the tissue to improve the appearance of the treatment site.

Abstract: Treatment systems, methods, and apparatuses for improving the appearance of skin or other target regions are described as well as for providing for other treatments. Aspects of the technology are directed to improving the appearance of skin by tightening the skin, improving skin tone or texture, eliminating or reducing wrinkles, increasing skin smoothness, or improving the appearance of cellulite. Treatments can include cooling a surface of a patient's skin and detecting at least one freeze event in the cooled skin. The treatment system can continue cooling the patient's skin after the freeze event(s) are detected so to maintain at least a partially frozen state of the tissue for a period of time.

Abstract: Compositions and formulations for use with devices and systems that enable tissue cooling, such as cryotherapy applications, for alteration and reduction of adipose tissue are described. Aspects of the technology are further directed to methods, compositions and devices that provide protection of non-targeted cells (e.g., non-lipid-rich cells) from freeze damage during dermatological and related aesthetic procedures that require sustained exposure to cold temperatures. Further aspects of the technology include systems for enhancing sustained and/or replenishing release of cryoprotectant to a treatment site prior to and during cooling applications.

Abstract: Light sources and methods for spreading a beam of electromagnetic radiation. The light sources include a scattering element with an outlet and an angular-selective element with an inlet spatially disposed between the outlet of the scattering element and an electromagnetic radiation source. The beam enters the inlet traveling in a direction of propagation and propagates through the beam spreader to the outlet for transmission from the outlet. The scattering element includes a scattering medium configured to scatter the electromagnetic radiation in the beam to provide a two-dimensional spatial distribution for intensity that is substantially uniformly across the outlet. The angular-selective element is configured to reflect a majority of the electromagnetic radiation of the first beam scattered by the scattering medium in a direction opposite to the propagation direction and reaching the angular-selective element.

Abstract: In a fractional treatment system, an adjustable mechanism can be used to adjust the beam shape, beam numerical aperture, beam focus depth, and/or beam size to affect the treatment depth and or the character of the resulting lesions. Adjustment of these parameters can improve the efficiency and efficacy of treatment. Illustrative examples of adjustable mechanisms include a set of spacers of different lengths, a rotatable turret with lens elements of different focal distances, an optical zoom lens, and a mechanical adjustment apparatus for adjusting the spacing between two optical lens elements. In one aspect, the fractional treatment is configured with a laser wavelength that is selected such that absorption of the laser wavelength within the tissue decreases as the tissue is heated by the laser (e.g., 1480-1640 nm).

Abstract: Optical pattern generators use rotating reflective axicon segments to produce images that can have different dimensions along the pattern direction compared to the cross pattern direction. Examples include both single axicon pattern generators and dual axicon pattern generators that independently control the image space relative aperture and thereby control the image dimensions in two orthogonal directions.

Abstract: A fractional treatment system can be configured with a laser wavelength that is selected such that absorption of the laser wavelength within the tissue increases as the tissue is heated by the laser (e.g., 1390-1425 nm). Desirably, the laser wavelength is primarily absorbed within a treated region of skin by water and has a thermally adjusted absorption coefficient within the range of about 8 cm?1 to about 30 cm?1. An adjustable mechanism can be used to adjust the beam shape, beam numerical aperture, beam focus depth, and/or beam size to affect the treatment depth and or the character of the resulting lesions. The system may be designed to be switchable between a treatment mode that is semi-ablative and a treatment mode that is not semi-ablative. Adjustment of these parameters can improve the efficiency and efficacy of treatment.

Abstract: An optical pattern generator uses reflection from multiple (e.g., two) internal mirror surfaces mounted on a rotating support structure.

Abstract: A method of restoring hair to skin that has suffered hair loss includes optically ablating an array of spaced-apart microchannels or voids into the skin and transplanting into the voids stem cells, a scaffold and a differentiation factor for causing the stem cells to differentiate into hair follicles.

Abstract: A method of restoring hair to skin that has suffered hair loss includes optically ablating an array of spaced-apart microchannels or voids into the skin and transplanting into the voids stem cells, a scaffold and a differentiation factor for causing the stem cells to differentiate into hair follicles.

Abstract: Light sources and methods for spreading a beam of electromagnetic radiation. The light sources include a scattering element with an outlet and an angular-selective element with an inlet spatially disposed between the outlet of the scattering element and an electromagnetic radiation source. The beam enters the inlet traveling in a direction of propagation and propagates through the beam spreader to the outlet for transmission from the outlet. The scattering element includes a scattering medium configured to scatter the electromagnetic radiation in the beam to provide a two-dimensional spatial distribution for intensity that is substantially uniformly across the outlet. The angular-selective element is configured to reflect a majority of the electromagnetic radiation of the first beam scattered by the scattering medium in a direction opposite to the propagation direction and reaching the angular-selective element.

Abstract: An optical pattern generator uses reflection from multiple (e.g., two) internal mirror surfaces mounted on a rotating support structure.

Abstract: An optical pattern generator uses reflection from multiple (e.g., two) internal mirror surfaces mounted on a rotating support structure.