Toward reproducible tumor organoid culture: focusing on primary liver cancer.

Organoids present substantial potential for pushing forward preclinical research and personalized medicine by accurately recapitulating tissue and tumor heterogeneity in vitro. However, the lack of standardized protocols for cancer organoid culture has hindered reproducibility. This paper comprehensively reviews the current challenges associated with cancer organoid culture and highlights recent multidisciplinary advancements in the field with a specific focus on standardizing liver cancer organoid culture. We discuss the non-standardized aspects, including tissue sources, processing techniques, medium formulations, and matrix materials, that contribute to technical variability. Furthermore, we emphasize the need to establish reproducible platforms that accurately preserve the genetic, proteomic, morphological, and pharmacotypic features of the parent tumor. At the end of each section, our focus shifts to organoid culture standardization in primary liver cancer. By addressing these challenges, we can enhance the reproducibility and clinical translation of cancer organoid systems, enabling their potential applications in precision medicine, drug screening, and preclinical research.

Bile duct injury with formation of right hepatic duct-duodenal fistula after cholecystectomy: A case report.

RATIONALE: The management of bile duct injury (BDI) remains a considerable challenge in the department of hepatobiliary and pancreatic surgery. BDI is mainly iatrogenic and mostly occurs in laparoscopic cholecystectomy (LC). After more than 2 decades of development, with the increase in experience and technological advances in LC, the complications associated with the procedure have decreased annually. However, bile duct injuries (BDI) still have a certain incidence, the severity of BDI is higher, and the form of BDI is more complex. PATIENT CONCERNS: We report the case of a patient who presented with bile duct injury and formation of a right hepatic duct-duodenal fistula after LC. DIAGNOSES: Based on the diagnosis, a dissection was performed to relieve bile duct obstruction, suture the duodenal fistula, and anastomose the right and left hepatic ducts to the jejunum. INTERVENTION: Based on the diagnosis, a dissection was performed to relieve bile duct obstruction, suture the duodenal fistula, and anastomose the right and left hepatic ducts to the jejunum. OUTCOMES: Postoperative recovery was uneventful, with normal liver function and no complications, such as anastomotic fistula or biliary tract infection. The patient was hospitalized for 11 days postoperatively and discharged. LESSONS: The successful diagnosis and treatment of this case and the summarization of the imaging features and diagnosis of postoperative BDI have improved the diagnostic understanding of postoperative BDI and provided clinicians with a particular clinical experience and basis for treating such diseases.

Multifunctional Organic-Inorganic Hybrid Perovskite Microcrystalline Engineering and Electromagnetic Response Switching Multi-Band Devices.

High-efficiency electromagnetic (EM) functional materials are the core building block of high-performance EM absorbers and devices, and they are indispensable in various fields ranging from industrial manufacture to daily life, or even from national defense security to space exploration. Searching for high-efficiency EM functional materials and realizing high-performance EM devices remain great challenges. Herein, a simple solution-process is developed to rapidly grow gram-scale organic-inorganic (MAPbX3 , X = Cl, Br, I) perovskite microcrystals. They exhibit excellent EM response in multi bands covering microwaves, visible light, and X-rays. Among them, outstanding microwave absorption performance with multiple absorption bands can be achieved, and their intrinsic EM properties can be tuned by adjusting polar group. An ultra-wideband bandpass filter with high suppression level of -71.8 dB in the stopband in the GHz band, self-powered photodetectors with tunable broadband or narrowband photoresponse in the visible-light band, and a self-powered X-ray detector with high sensitivity of 3560 µC Gyair -1  cm-2  in the X-ray band are designed and realized by precisely regulating the physical features of perovskite and designing a novel planar device structure. These findings open a door toward developing high-efficiency EM functional materials for realizing high-performance EM absorbers and devices.

High-Performance UV-Vis Broad-Spectra Photodetector Based on a ß-Ga2O3/Au/MAPbBr3 Sandwich Structure.

The UV-vis photodetector (PD), a detector that can simultaneously detect light in the ultraviolet region and the visible region, has a wide range of applications in military and civilian fields. Currently, it is very difficult to obtain good detection performance in the UV region (especially in the solar-blind range) like in the visible region with most UV-vis PDs. This severely affects the practical application of UV-vis broad-spectra PDs. Here, a simple sandwich structure PD (SSPD) composed of ß-Ga2O3, Au electrodes, and the MAPbBr3 perovskite is designed and fabricated to simultaneous enhance the detection performance in the UV and visible light regions. The ß-Ga2O3/Au/MAPbBr3 SSPD exhibits enhanced optoelectronic performance with high responsivities of 0.47 and 1.43 A W-1 at 240 and 520 nm under a bias of 6 voltage (V), respectively, which are 8.5 and 23 times than that of the metal-semiconductor-metal (MSM) structure MAPbBr3 PD at 6 V, respectively. The enhanced performance was attributed to the effective suppression of carrier recombination due to the efficient interface charge separation in the device structure. In addition, the self-powered response characteristic is also realized by forming a type-II heterojunction between ß-Ga2O3 and MAPbBr3, which gives the ß-Ga2O3/Au/MAPbBr3 SSPD superior single-pixel photo-imaging ability without an external power supply. This work provides a simple and effective method for the preparation of high-performance self-powered imaging PDs in the UV-visible region.

Regulating interface Schottky barriers toward a high-performance self-powered imaging photodetector.

Two-dimensional (2D) layered organic-inorganic hybrid perovskites have attracted wide attention in high-performance optoelectronic applications due to their good stability and excellent optoelectronic properties. Here, a high-performance self-powered photodetector is realized based on an asymmetrical metal-semiconductor-metal (MSM) device structure (Pt-(PEA)2PbI4 SC-Ag), which introduces a strong built-in electric field by regulating interface Schottky barriers. Benefitting from excellent built-in electrical potential, the photodetector shows attractive photovoltaic properties without any power supply, including high photo-responsivity (114.07 mA W-1), fast response time (1.2 µs/582 µs) and high detectivity (4.56 × 1012 Jones). Furthermore, it exhibits high-fidelity imaging capability at zero bias voltage. In addition, the photodetectors show excellent stability by maintaining 99.4% of the initial responsivity in air after 84 days. This work enables a significant advance in perovskite SC photodetectors for developing stable and high-performance devices.

Multilinear Discriminative Spatial Patterns for Movement-Related Cortical Potential Based on EEG Classification with Tensor Representation.

The discriminative spatial patterns (DSP) algorithm is a classical and effective feature extraction technique for decoding of voluntary finger premovements from electroencephalography (EEG). As a purely data-driven subspace learning algorithm, DSP essentially is a spatial-domain filter and does not make full use of the information in frequency domain. The paper presents multilinear discriminative spatial patterns (MDSP) to derive multiple interrelated lower dimensional discriminative subspaces of low frequency movement-related cortical potential (MRCP). Experimental results on two finger movement tasks' EEG datasets demonstrate the effectiveness of the proposed MDSP method.

Multistability of complex-valued neural networks with discontinuous activation functions.

In this paper, based on the geometrical properties of the discontinuous activation functions and the Brouwer's fixed point theory, the multistability issue is tackled for the complex-valued neural networks with discontinuous activation functions and time-varying delays. To address the network with discontinuous functions, Filippov solution of the system is defined. Through rigorous analysis, several sufficient criteria are obtained to assure the existence of 25n equilibrium points. Among them, 9n points are locally stable and 16n-9n equilibrium points are unstable. Furthermore, to enlarge the attraction basins of the 9n equilibrium points, some mild conditions are imposed. Finally, one numerical example is provided to illustrate the effectiveness of the obtained results.

Matrix measure method for global exponential stability of complex-valued recurrent neural networks with time-varying delays.

In this paper, based on the matrix measure method and the Halanay inequality, global exponential stability problem is investigated for the complex-valued recurrent neural networks with time-varying delays. Without constructing any Lyapunov functions, several sufficient criteria are obtained to ascertain the global exponential stability of the addressed complex-valued neural networks under different activation functions. Here, the activation functions are no longer assumed to be derivative which is always demanded in relating references. In addition, the obtained results are easy to be verified and implemented in practice. Finally, two examples are given to illustrate the effectiveness of the obtained results.

CD44+ CD133+ population exhibits cancer stem cell-like characteristics in human gallbladder carcinoma.

Cancer stem cells (CSCs)/tumor-initiating cells have been defined as a subset of tumor cells responsible for initiating and sustaining tumor development. Emerging evidence strongly supports the existence of CSCs in various solid tumors, but they have not yet been identified in human gallbladder carcinomas (GBC). In this study, we identified CSCs in primary GBC and in the cell line GBC-SD using the cell surface markers CD44 and CD133. The percentages of CD44+CD133+ cells were 1.76-3.05% in primary tumors and 40.29% in GBC-SD cells. These cells showed stem cell properties, including self-renewal, differentiation potential, and high tumorigenicity. In vitro culture experiments revealed that CD44+CD133+ GBC cells possessed a higher spheroid-colony forming ability in serum-free media than other subpopulations. When injected into nonobese diabetic/severe combined immunodeficient mice, these cells formed new tumors and generated CD44+CD133+, CD44-, and CD133- progeny. CD44+CD133+ cells also showed a high degree of chemoresistance, possibly due to upregulation of the breast cancer resistance protein (ABCG2) and the transcription factor Gli1 in these highly tumorigenic cells. These results suggest that the CD44+CD133+ population exhibited CSC-like characteristics and may thus provide a novel approach to the diagnosis and treatment of GBC.