Objective To establish a gradient RP￣HPLC method for determining the related substances in lumefantrine. Methods The HPLC analysis was performed on an Agilent nucleosil 100￣5 C18(4.0 mm×125 mm,5 μm) column;the mobile phase was consisted of solution A,B and C,which included phosphate buffer solutions (consisting sodium hexane sulfonate,pH was adjusted to 2. 3 )￣water￣acetonitrile￣propanol with different proportion, with a gradient elution at the flow rate of 2.0 mL.min-1 , the detection wavelength was 265 nm, and the column temperature was 35 ℃ . Results An excellent separation achieved for lumefantrine from its related substances.Lumefantrine had a good linear relationship with the peak area within the range of 0.173 4-0.693 2 μg.mL-1(r= 0.999 6).The limit of determination was 0.06 μg.mL-1 . Conclusion The method is sensitive,reproducible and specific for the separation and determination of related substances in lumefantrine.

Breast implant-associated anaplastic large cell lymphoma (BIA-ALCL) is a rare type of T-cell lymphoma. Despite the scarcity of reported BIA-ALCL cases in Asia, it is imperative to research early diagnosis. The crucial diagnostic criteria for BIA-ALCL include the presence of ALK - and CD30 + T cells exceeding 10% in the delayed seroma fluid. Furthermore, laboratory tests, such as histological examination of capsulectomies and analysis of clonal T-cell receptor (TCR) gene rearrangements, serve as important auxiliary diagnostic indicators. This article reported the case of a 56-year-old female patient who underwent bilateral breast augmentation with implants over 20 years ago. She presented with hardness, enlargement, and mild discomfort in her left breast. She was admitted to Shanghai Ninth People’s Hospital, Shanghai Jiao Tong University School of Medicine in January 2023. MRI suggested implant rupture. Therefore, bilateral implant removal surgery was performed on February 2, 2023. Pathological examination of the fluid within the capsule of the left implant revealed a small number of ALK - and CD30 + T cells, with monoclonality observed in TCRγ gene rearrangement, indicating early changes suggestive of BIA-ALCL. Long-term follow-up is needed. The authors suggest that patients suspected of BIA-ALCL should undergo TCR gene rearrangement testing in addition to cytological and immunological examinations, which can provide guidance for the diagnosis, treatment, and necessary long-term follow-up of these patients.

Breast implant-associated anaplastic large cell lymphoma (BIA-ALCL) is a rare type of T-cell lymphoma. Despite the scarcity of reported BIA-ALCL cases in Asia, it is imperative to research early diagnosis. The crucial diagnostic criteria for BIA-ALCL include the presence of ALK - and CD30 + T cells exceeding 10% in the delayed seroma fluid. Furthermore, laboratory tests, such as histological examination of capsulectomies and analysis of clonal T-cell receptor (TCR) gene rearrangements, serve as important auxiliary diagnostic indicators. This article reported the case of a 56-year-old female patient who underwent bilateral breast augmentation with implants over 20 years ago. She presented with hardness, enlargement, and mild discomfort in her left breast. She was admitted to Shanghai Ninth People’s Hospital, Shanghai Jiao Tong University School of Medicine in January 2023. MRI suggested implant rupture. Therefore, bilateral implant removal surgery was performed on February 2, 2023. Pathological examination of the fluid within the capsule of the left implant revealed a small number of ALK - and CD30 + T cells, with monoclonality observed in TCRγ gene rearrangement, indicating early changes suggestive of BIA-ALCL. Long-term follow-up is needed. The authors suggest that patients suspected of BIA-ALCL should undergo TCR gene rearrangement testing in addition to cytological and immunological examinations, which can provide guidance for the diagnosis, treatment, and necessary long-term follow-up of these patients.

Objective To evaluate the environmental radioactive safety level in China, monitor the radioactivity of strontium-90 (⁹⁰Sr) in seafood from selected marine regions of China, and optimize the di-(2-ethylhexyl)phosphoric acid (HDEHP) extraction chromatography method for determining Sr-90 in seafood. Methods In 2023, seafoods of fish, shrimp, shellfish, and seaweed were collected from the Shandong Province (Bohai Sea and Yellow Sea) and Hainan Province (South China Sea). The levels of Sr in the samples were determined by inductively coupled plasma atomic emission spectrometer (ICP-AES). The ⁹⁰Sr separation were performed using HDEHP extraction chromatography, while the recovery of ⁹⁰Sr were determined by the gravitmetry with the assistant of ICP-AES. Results The content of strontium in seafoods varies greatly, and excessive strontium and calcium in seafood may lead to overestimated recovery due to insufficient leaching during chromatographic separation by HDEHP extraction. Therefore, the yttrium content in the eluent should be analyzed by ICP . The radioactivity of ⁹⁰Sr in seafood from the sea areas in Shandong Province was 0.22-1.85 Bq/kg (dry weight), and that of seafood from Hainan Province was 0.19-1.82 Bq/kg (dry weight). Conclusion For the analysis of shirmp and seaweed samples, the recovery rate of ⁹⁰Sr should be analyzed using both gravimetry and ICP-AES. There is no significant linear correlation between total Sr and ⁹⁰Sr in seafood. There is no significant difference in ⁹⁰Sr radioactivity between the seafood samples collected from Shandong and Hainan. The ⁹⁰Sr radioactivity levels of all 28 samples are below the limit specified in the Limited concentrations of radioactive materials in foods (GB 14882—1994) and are within the range of environmental background fluctuations.

Objective To organize a nationwide interlaboratory comparison for measurement of gross α and gross β radioactivity in water, and improve the laboratory analysis of gross α and gross β radioactivity in water. Methods A unified comparison protocol was developed by the organizers. The groundwater with high natural radioactivity was used as water sample and distributed randomly to the participating laboratories. The participating laboratories used routine analytical methods to measure the samples and provided information such as analytical results, original records, and test reports. The results were evaluated using z-score. Results A total of 76 laboratories participated in the comparison, all employing the evaporation concentration-α/β counting method. Among them, 69 laboratories achieved |z| ≤ 2 for both gross α and gross β radioactivity measurements, and 32 laboratories achieved |z| ≤ 0.50 for both gross α and gross β radioactivity measurements. There were 69 laboratories with qualified results and 30 laboratories with excellent results, yielding a qualified rate of 90.8% and an excellent rate of 39.5%. Seven laboratories showed unqualified results and the unqualified rate was 9.2%. Conclusion Most laboratories have the ability to analyze gross α and gross β radioactivity in water. The main reasons for the deviation in comparison results are calibration efficiency, errors in the total residue mass caused by improper water sample processing operations. By analyzing the main technical problems existed in unqualified laboratories, their ability for measurement of gross α and gross β radioactivity in water has been improved.