Clinical and Pathological Analysis of 10 Cases of Eosinophilic Pustular Folliculitis.

We conducted a retrospective analysis of clinical and pathologic data from January 2020 to June 2023, focusing on 10 patients diagnosed with eosinophilic pustular folliculitis at our dermatology clinic. Four of the ten patients had the first rash on the face, five on the trunk, and one on the palms and feet, all of which were initially scattered papules that gradually increased and fused into erythematous plaques with a circular distribution. Seven had pustules with small surface desquamation, and three cases had micro swelling on the face. The rash involved only the face in 5 cases, the face and trunk in 5 cases, and the face, trunk, hands, and feet in 1 case. Seven of the ten patients were pruritic, and 3 had no obvious pruritus. The histopathological features were mild epidermal hyperplasia, lymphocytic and eosinophilic infiltration around the superficial middle dermal vessels and appendages, and eosinophilic and neutrophilic abscesses in the local hair follicles. Treatment with oral indomethacin, prednisone, and minocycline was effective.

Improved thermal conductivity and excellent electrical insulation properties of polysiloxane nanocomposite-incorporated functional boron nitride sheets via in situ polymerization.

Benefiting from its high thermal conductivity (κ) and superior insulation, the boron nitride nanosheet (BNNS) is widely investigated as a promising filler for thermal nanocomposites. However, poor dispersibility and weak interaction with polymer matrix hinder the further improvement of BNNS-based thermal composites. Here, inspired by side-chain liquid crystal polysiloxane (SCLCP) with good mesomorphic structures, highly thermoconductive nanocomposites prepared via in situ polymerization using SCLCP with 2D BNNS are reported. The surface of BNNS is silanized with γ-(methacryloxy)propyltrimethoxysilane (KH-570) to introduce double bonds (defined as f-BNNS), and it is directly linked with SCLCP chains during polymerization. Therefore, the alternating stacking of f-BNNS and microscopic ordered structure of SCLCP yielded a high κ of 2.463 W m-1 K-1 at only 30 wt% f-BNNS content, improving dramatically the κ of pure SCLCP by ∼9 times. Further, the volume electrical resistivity reached 2.11 × 1014 Ω cm, which is five orders of magnitude higher than the critical resistance for electrical insulation (109 Ω cm). Also, the f-BNNS/SCLCP composites as thermal management materials decreased the temperature of the LED chip by 17.5 °C, exhibiting superior thermal management performance. Along with high κ and excellent electrical resistance, this type of nanocomposites displays great advantages in thermal properties for electronic packaging and thermal management of electronics.

Prurigo Pigmentosa Successfully Treated with Oral Minocycline: A Case Report.

Purpose: We aimed to report a case of prurigo pigmentosa (PP) with blisters. Patients and Methods: A 21-year-old male patient presented to our hospital with erythema, papules, and blisters all over the front chest and back. Densely distributed round and oval edematous erythema was noted on the neck, front chest, and back of the patient. Histopathologic examination of the skin lesions (blisters) on the chest revealed epidermal cell hyperkeratosis. He was diagnosed with PP and was treated with oral minocycline. Results: After 1-week minocycline administration, the patient's itching was relieved, and the blisters dried up. His skin lesions recurred following self-withdrawal from the medication; subsequently, the patient was administered oral minocycline treatment again. After 1-month continuous oral treatment, the drug was discontinued. No recurrence of symptoms was noted. Conclusion: Oral minocycline is effective for the treatment of PP.

Design and analysis of in-plane and out-of-plane heterostructures based on monolayer tri-G with enhanced photocatalytic property for water splitting.

Photocatalytic water splitting is considered to be a promising renewable solution to the energy crisis and environmental problems as an inexhaustible clean energy source. Graphene has an ultrahigh carrier mobility, but the zero gap limits its practical application in the photocatalysis field. Graphane has a wider band gap and retains a high carrier mobility, which demonstrates its great potential in this field. However, the broad band gap results in low photocatalytic efficiency. In this work, we propose two effective ways to modulate its electronic structure, modifying the structure of graphane and constructing a heterojunction using density functional calculations. We systematically investigated four trilayer graphane (tri-G) conformers and designed in-plane (lateral) and out-of-plane (vertical) heterojunctions with tri-G and chair-G (cha-G), the two most stable graphanes, with theoretical prediction. The results show that tri-G not only has a smaller band gap, falling in the ultraviolet range, which enhances the UV-light catalytic performance, but also has tunable band edge positions, locating outside the reduction potential of hydrogen and oxidation potential of water. Furthermore, the calculated electron effective mass for the tri-G conformers is smaller than that of cha-G. What's more, the band gap, band edge position, and photocatalytic efficiency are further optimized by constructing heterojunctions. In particular, both the in-plane and out-of-plane tri-G-C/cha-G heterostructures are confirmed as direct band gap semiconductors and type-I heterostructures exhibiting special band alignment, meanwhile satisfying the requirements for water splitting. And the band gaps of the heterostructures are further reduced. In addition, metal doping is expected to further optimize their electronic structure. These results provide theoretical support and a feasible modulation strategy for developing graphane as an effective photocatalyst for water splitting.

An efficient utilization of chromium-containing vanadium tailings: Extraction of chromium by soda roasting-water leaching and preparation of chromium oxide.

Chromium-containing vanadium tailings (CCVT), an industrial waste, were utilized to extract chromium efficiently by soda roasting-water leaching process and for the preparation of highly pure chromium oxide. The effect of extraction of chromium under different roasting and leaching conditions were analyzed using X-ray diffraction (XRD) and scanning electron microscopy (SEM). The maximum chromium extraction rate of 91.51% was obtained when soda (Na2CO3) and CCVT were mixed in a molar ratio (n (Na2CO3)/n (Cr2O3)) of 8, roasted at 900 °C and maintained for 120 min. Then, the roasted product was leached in water at 60 °C for 60 min with a liquid-solid mass ratio (L/S) of 10. During soda roasting, the chromium-containing phase (Fe0.6Cr0.4)2O3 combines with Na2CO3 to form Na2CrO4, which was then transferred into the leaching liquid, post water leaching. The by-products such as NaFeTiO4, Na2CaSiO4, and Na0.68Fe0.68Si0.32O2 were left in the leaching residue which was called chromium tailings (CT). 87.40% chromium oxide was recovered from the unpurified leaching liquid after reduction and precipitation by adding Na2S, followed by roasting the deposit. This process not only relieved the potential threat of the industrial waste CCVT to the environment but also realized the recovery of the valuable element chromium.