Picosecond Alexandrite Laser With Diffractive Lens Array Combined With Long-Pulse Alexandrite Laser for the Treatment of Facial Photoaging in Chinese Women: A Retrospective Study.

BACKGROUND AND OBJECTIVES: Facial photoaging is a type of facial skin aging induced mainly by exogenous factors (ultraviolet radiation) and often manifests itself in the form of hyperpigmentation, telangiectasia, roughness, increase in fine lines/wrinkles, and enlarged pores. Recently, picosecond lasers have become an emerging option for the treatment of facial photoaging, and long-pulse alexandrite lasers (LPAL) have demonstrated promising potential in the treatment of photoaging-related symptoms. This study aimed to evaluate the efficacy and safety of picosecond alexandrite laser (PSAL) with diffractive lens array (DLA) combined with LPAL for facial photoaging. METHODS: This is a retrospective study of 20 Chinese female patients with facial photoaging who received PSAL with DLA combined with LPAL during a 1-year period. All patients were treated every 4 weeks for a total of three treatments. Objective indicators of facial photoaging and patient satisfaction were evaluated before each treatment, and pain scores and adverse effects were recorded after each treatment. RESULTS: Compared with baseline, patients showed significant differences in all facial photoaging indices (p < 0.01). After receiving three treatments, there was a 20.1% decrease in the pigmentation index, a 23.9% decrease in the erythema index, a 34.5% decrease in the texture index, a 28.4% decrease in the fine lines index, a 56% decrease in the pore index, a 9.3% elevation and a 17.1% decrease in elasticity R2 and F4, respectively, and a 55% decrease in sebum content. The mean satisfaction score for the three treatments was 4.67 (3.33, 5.00), and the mean visual analogue scale (VAS) pain score was 7.00. No serious adverse effects such as post-inflammatory hyperpigmentation (PIH), hypopigmentation, or blistering were observed at the treatment site during the treatment period. CONCLUSION: PSAL with DLA combined with LPAL for the treatment of facial photoaging with significant efficacy, high patient satisfaction, and minimal adverse effects.

Safety and efficacy of a picosecond 755-nm alexandrite laser combined with topical tranexamic acid in the treatment of melasma.

BACKGROUND: The picosecond 755-nm alexandrite laser and topical tranexamic acid (TA) have shown promise in treating melasma. AIM: This aim of this study was to evaluate the efficacy and safety of combining to a picosecond 755-nm alexandrite laser combined with topical TA for melasma treatment. PATIENTS AND METHODS: Forty-eight patients' facial halves with bilateral symmetrical melasma were randomized to receive either topical TA and picosecond laser treatment or laser monotherapy. All patients received three consecutive picosecond laser treatment sessions at 4-week intervals, and additional one side facial received topical TA treatment twice daily until 4 weeks after the third treatments. Efficacy was assessed using the Modified Melasma Area and Severity Index (mMASI) score, VISIA (Canfield, USA) red area feature counts, and average pore volume as measured by Antera 3D®. Patient satisfaction was evaluated through questionnaires. RESULTS: Thirty-five patients completed the study. Post-treatment, mMASI scores and VISIA red area feature counts were lower in combination therapy halves and laser monotherapy halves, and average melanin level was lower in the combination therapy halves (p < 0.05). Comparisons between the combination therapy halves and laser monotherapy halves after the third treatment revealed significant differences in mMASI scores, melanin levels, and VISIA red area feature counts (p < 0.05). After treatment, patient satisfaction rates in the combination therapy halves and monotherapy halves was 71.4% and 54.3%, respectively (p < 0.05). No obvious adverse effects were observed in the combination therapy halves; whereas, 10.42% (5/48) of participants in the laser monotherapy halves experienced temporary pigmentation, which resolved within 3 months. CONCLUSION: The picosecond 755-nm alexandrite laser, when used independently and in combination with topical TA, has been proven to be effective in the improvement of melasma. However, the combined treatment approach showed a more pronounced improvement in melasma symptoms, with higher patient satisfaction, and was associated with a lower incidence of adverse effects. These findings strongly support that integrating topical TA with picosecond laser therapy as a superior therapeutic strategy for melasma management. CLINICAL TRIAL REGISTRATION: Chinese Clinical Trial Registry: ChiCTR2200057771.

Realization of Joints of Aluminosilicate Glass and 6061 Aluminum Alloy via Picosecond Laser Welding without Optical Contact.

To achieve laser direct welding of glass and metal without optical contact is hard, owing to the large difference in thermal expansion and thermal conductivity between glass and metal and an insignificant melting area. In this study, the high-power picosecond pulsed laser was selected to successfully weld the aluminosilicate glass/6061 aluminum alloy with a gap of 35 ± 5 µm between glass and metal. The results show that the molten glass and metal diffuse and mix at the interface. No defects such as microcracks or holes are observed in the diffusion mixing zone. Due to the relatively large gap, the glass collapsed after melting and caulking, resulting in an approximately arc-shaped microcrack between modified glass and unmodified glass or weakly modified glass. The shape of the glass modification zone and thermal accumulation are influenced by the single-pulse energy and linear energy density of the picosecond laser during welding, resulting in variations in the number and size of defects and the shape of the glass modification zone. By reasonably tuning the two factors, the shear strength of the joint reaches 15.98 MPa. The diffusion and mixing at the interface and the mechanical interlocking effect of the glass modification zone are the main reasons for achieving a high shear strength of the joint. This study will provide reference and new ideas for the laser transmission welding of glass and metal in the non-optical contact conditions.

Picosecond 532 nm Laser: An Optimal Device for the Reduction of Acquired Agminated Nevi.

OBJECTIVES: Agminated nevi are rare, grouped lesions, which are confined to one anatomic area. Herein, we report a case of successful cosmetic treatment of bilateral, acquired agminated nevi with a picosecond 532 nm Nd:YAG laser device. MATERIALS AND METHODS: Literature search was completed on acquired agminated nevi. A healthy 21-year-old woman presented with numerous, grouped 1-mm brown-to-dark brown macules in the axillae bilaterally. Biopsies revealed lentiginous junctional nevi with mild atypia, leading to the diagnosis of agminated nevi. She was referred for laser treatment to improve cosmetic appearance. Two different laser devices were utilized initially, a picosecond 532 nm Nd:YAG laser on the left axilla and a millisecond domain 532 nm laser on the right. Greater improvement was noted with the picosecond 532 nm device. Three additional treatments were completed with the picosecond laser with significant improvement in pigmentation of melanocytic nevi. RESULTS: Various pigmented and melanocytic lesions have been noted to occur in an agminated pattern although their pathway of development remains unknown. While various devices have demonstrated efficacy for pigmented lesions, treatment of agminated nevi specifically is less reported or established. Our patient's presentation is novel because of the axillary location and bilateral distribution of multiple acquired agminated nevi, neither of which have been previously reported in the literature. We also report successful treatment utilizing a picosecond 532 nm laser. While laser can help improve the cosmetic appearance of pigmented lesions, most lasers do not remove all melanocytes, highlighting the need for close monitoring, as atypia and melanoma have been reported to develop in acquired agminated nevi. CONCLUSION: Thus, we present a case of acquired agminated nevi in a novel bilateral distribution in a healthy female successfully treated with a picosecond 532 nm laser.

Elastic Modulus Measurement at High Temperatures for Miniature Ceramic Samples Using Laser Micro-Machining and Thermal Mechanical Analyzer.

In this paper, we demonstrate a method of measuring the flexural elastic modulus of ceramics at an intermediate (~millimeter) scale at high temperatures. We used a picosecond laser to precisely cut microbeams from the location of interest in a bulk ceramic. They had a cross-section of approximately 100 µm × 300 µm and a length of ~1 cm. They were then tested in a thermal mechanical analyzer at room temperature, 500 °C, 800 °C, and 1100 °C using the four-point flexural testing method. We compared the elastic moduli of high-purity Al2O3 and AlN measured by our method with the reported values in the literature and found that the difference was less than 5% for both materials. This paper provides a new and accurate method of characterizing the high-temperature elastic modulus of miniature samples extracted from representative/selected areas of bulk materials.

Dual-Method Characterization and Optimization of Drilling Parameters for Picosecond Laser Drilling Quality in CFRP.

Carbon fiber-reinforced polymer (CFRP), known for its light weight, high strength, and corrosion-resistant properties, is extensively used in the lightweight design of satellite components, the optimization of electronic device casings, and the processing of high-performance composite materials in the defense sector. This study employs picosecond laser drilling technology for the precision machining of CFRP, demonstrating its advantages over traditional mechanical drilling and other unconventional methods in significantly reducing the heat-affected zone (HAZ) and enhancing hole wall quality. The optimization of laser power, scanning speed, and fill times via response surface methodology (RSM) significantly reduced the hole wall taper to 4.160° and confined the HAZ to within 18.577 µm, thereby enhancing machining precision. The actual test results show that the deviations in the hole taper and HAZ width were 5.0% and 2.2%, respectively, further verifying the effectiveness of the optimization method. This technique not only improves processing quality but also offers significant industrial application value in the machining of materials for related high-tech fields.

GPCR Signaling: A Study of the Interplay Between Structure, Energy, and Function.

G protein-coupled receptors (GPCRs) exemplify sophisticated allosteric communication, transducing extracellular signals through ligand-induced structural rearrangements that resonate through the molecular scaffold. Despite extensive study, the biophysical underpinnings of how conformational changes spread remain unclear. This work employs a novel physics-based framework to characterize the role of energy dissipation in directing intramolecular signaling pathways. By modeling each residue as a network of coupled oscillators, we generate a localization landscape depicting the vibrational energy distribution throughout the protein scaffold. Quantifying directional energy flux between residues reveals distinct pathways for energy and information transfer, illuminating sequences of allosteric communication. Our analysis of CB1 and CCR5 crystal structures unveils an anisotropic pattern of energy dissipation aligning with key functional dynamics, such as activation-related conformational changes. These anisotropic patterns of vibrational energy flow constitute pre-configured channels for allosteric signaling. Elucidating the relationship between structural topology and energy dissipation patterns provides key insights into the thermodynamic drivers of conformational signaling. This methodology significantly advances our mechanistic understanding of allostery in GPCRs and presents a broadly applicable approach for rationally dissecting allosteric communication pathways, with potential implications for structure-based drug design targeting these critical receptors.

Effect of fractional picosecond laser therapy using a diffractive optical lens on histological tissue reaction.

BACKGROUND AND OBJECTIVES: Fractional ablative resurfacing techniques are preferred treatments for facial rejuvenation of aged skin. This study was performed to investigate the cutaneous effects of using a fractional picosecond laser at 1064 nm with a diffractive lens. METHODS: The penetration depth according to the location of the handpiece tip was evaluated using an acrylic panel. Laser induced optical breakdown (LIOB) and cutaneous damage were observed after hematoxylin and eosin staining in guinea pigs. Collagen formation was evaluated using Victoria staining, Masson's trichrome (MT) staining, and immunohistochemical staining for collagen type III. RESULTS: The penetration depth for LEVEL 1 was 499.98-935.23 µm (average: 668.75 ± 182.84 µm); the LIOB cavity area was 1664.17 ± 650.52 µm2. The penetration depth of LEVEL 2 was 257.12-287.38 µm (average: 269.77 ± 14.55 µm) with an LIOB cavity area of 1335.85 ± 214.41 µm2. At LEVEL 3, that was 36.17-53.69 µm (average: 52.15 ± 20.81 µm) and the LIOB cavity area was 1312.67 ± 1069.12 µm2. No epidermal tissue damage was observed and collagen formation was observed from day 14 under all conditions. CONCLUSION: Diffractive optical element (DOE) lens arranged laser treatment system controlled the position of LIOB occurrence and an irradiating area.

Efficacy of 532-nm Nd: YAG Fractional Picosecond Laser with 9 mm High Coverage Handpiece Micro Lens Array in the Treatment of Facial Partial Unilateral Lentiginosis: A Case Report.

Introduction: Facial partial unilateral lentiginosis (PUL) is an infrequent skin pigmentation disorder characterized by multiple lentigines. Despite the availability of various treatment modalities, there is no standard treatment for PUL. This study reports a successful treatment of facial PUL in a female patient using a novel 532-nm Nd:YAG fractional picosecond laser (FPL). Case Report: The patient underwent four treatment sessions at four-week intervals. The treatments were administered using a 9 mm high coverage handpiece micro lens array (MLA), with a fluence of 0.2-0.4 J/cm2, a frequency of 2 Hz for 2-3 passes, and approximately 10% overlap. The treatment was well-tolerated by the patient, with significant improvement in pigmentation and no significant side effects observed. The outcomes confirmed the efficacy of the 532-nm Nd:YAG FPL in treating facial PUL. Conclusion: The 532-nm Nd:YAG FPL appears to be an effective and well-tolerated treatment for facial PUL, offering significant improvement in pigmentation without notable side effects.

Picosecond Ultrasonics in Magnetic Topological Insulator MnBi2Te4.

MnBi2Te4 is a magnetic topological insulator with layered A-type antiferromagnetic order. It exhibits a rich layer- and magnetic-state dependent topological phase diagram; however, much about the coupling between spin, charge, and lattice remains to be explored. In this work, we report that MnBi2Te4 is an excellent acoustic phonon cavity by realizing phonon frequency combs using picosecond ultrasonics. With the generated acoustic phonon wavepackets, we demonstrate that the timing and phase of acoustic echoes can be used to detect the presence of stacking faults between van der Waals layers buried deep within the crystal. Furthermore, by implementing this nondestructive ultrafast optical measurement in conjunction with time-resolved magneto-optical Kerr effect experiments, we uncover that out-of-plane vibrations in MnBi2Te4 do not couple to the magnetic order, i.e. there is no appreciable magnetostriction. Our work points out how a well-developed technique can probe the structural defects and phonon pulse engineering in layered topological insulators.