Anti-PD-1-based immunotherapy as curative-intent treatment in dMMR/MSI-H rectal cancer: A multicentre cohort study.

BACKGROUND: In a portion of patients with DNA mismatch repair-deficient (dMMR)/microsatellite instability-high (MSI-H) rectal cancer, clinical complete response (cCR) could be achieved after anti-programmed cell death protein 1 (anti-PD-1) immunotherapy. However, no data are available concerning the safety of omitting surgery and adopting immunotherapy as a curative-intent treatment for these patients. METHODS: We retrospectively collected a series of patients with dMMR/MSI-H rectal adenocarcinoma who had cCR after receiving anti-PD-1 immunotherapy and adopted immunotherapy as curative-intent treatment from six institutions. Survival outcomes were analysed using the Kaplan-Meier method. RESULTS: Nineteen patients were included with a median age of 48 (range 19-63). One patient was diagnosed with stage I disease, four with stage II disease and fourteen with stage III disease. Sixteen patients received anti-PD-1 immunotherapy as the first line of therapy, and eleven patients were treated with single-agent anti-PD-1 antibodies. The median time from the start of treatment to cCR was 3.8 (range 0.7-6.5) months. During a median follow-up of 17.1 (range 3.1-33.5) months since achieving cCR, no local or distant relapse was observed. Two-year local recurrence-free survival, distant metastasis-free survival, disease free-survival and overall survival for the whole cohort were 100%, 100%, 100% and 100%, respectively. CONCLUSIONS: For patients with dMMR/MSI-H locally advanced rectal cancer who achieved cCR during anti-PD-1 immunotherapy, adopting immunotherapy as curative-intent treatment might be an alternative option. Longer follow-up and larger cohorts are warranted to verify this innovative treatment approach.

MiR-224 Executes a Tumor Accelerative Role during Hepatocellular Carcinoma Malignancy by Targeting Cytoplasmic Polyadenylation Element-Binding Protein 3.

PURPOSE: The purpose of our study was to probe the mechanism of how miR-224/cytoplasmic polyadenylation element-binding protein 3 (CPEB3) axis is concerned with hepatocellular carcinoma (HCC). METHODS: The expressions and prognostic values of miR-224 and CPEB3 in HCC patients were analyzed based on the data acquired from the TCGA and GEO databases. qRT-PCR was conducted to test the mRNA expression levels of miR-224 and CPEB3. The expression level of miR-224 in SMMC-7721/HuH-7 cells was up-/downregulated by miR-224 mimic/inhibitor to explore its influence on HCC cell proliferation and motility by utilizing CCK8 and transwell assays, respectively. Luciferase activity assay was applied for verifying the target of miR-224. The relationship between miR-224 and CPEB3 was analyzed utilizing Pearson's correlation coefficient. The protein level of CPEB3 was tested by Western blotting. Rescue assay was performed to determine whether CPEB3 involved in the process of HCC cell phenotype changes caused by miR-224 alteration. RESULTS: MiR-224 was highly expressed and CPEB3 was lowly expressed in HCC tissues. Besides, the high expression of miR-224 and low expression of CPEB3 were correlated with worse prognosis in HCC patients. Up-/downregulation of miR-224 accelerated/restrained SMMC-7721/HuH-7 cell proliferation and motility. CPEB3 was predicted and proofed as a target gene of miR-224. We discovered that CPEB3 was negatively modulated by miR-224. We also found a sharply negative correlation between CPEB3 and miR-224. Using rescue assay, we showed that overexpression of CPEB3 suppressed the proliferation and motility of SMMC-7721 cells with overexpressed miR-224, while knockdown of CPEB3 facilitated the proliferation and motility of HuH-7 cells with downregulated miR-224. CONCLUSION: Our data provided evidences that miR-224 is implicated in HCC cell proliferation and motility via targeting CPEB3. The relationship between miR-224 and CPEB3 might be a novel finding, and miR-224/CPEB3 axis might be markers for providing therapeutic and prognostic information in HCC.

Doping-induced structural phase transition in cobalt diselenide enables enhanced hydrogen evolution catalysis.

Transition metal dichalcogenide materials have been explored extensively as catalysts to negotiate the hydrogen evolution reaction, but they often run at a large excess thermodynamic cost. Although activating strategies, such as defects and composition engineering, have led to remarkable activity gains, there remains the requirement for better performance that aims for real device applications. We report here a phosphorus-doping-induced phase transition from cubic to orthorhombic phases in CoSe2. It has been found that the achieved orthorhombic CoSe2 with appropriate phosphorus dopant (8 wt%) needs the lowest overpotential of 104 mV at 10 mA cm-2 in 1 M KOH, with onset potential as small as -31 mV. This catalyst demonstrates negligible activity decay after 20 h of operation. The striking catalysis performance can be attributed to the favorable electronic structure and local coordination environment created by this doping-induced structural phase transition strategy.

Cobalt-doping-induced synthesis of ceria nanodisks and their significantly enhanced catalytic activity.

High-quality cobalt-doped ceria nanostructures with triangular column, triangular slab, and disklike shapes are synthesized by tuning the doping amount of cobalt nitrate in a facile hydrothermal reaction. The cobalt-doped ceria nanodisks display significantly enhanced catalytic activity in CO oxidation due to exposed highly active crystal planes and the presence of numerous surface defects.

A DFT study of the structures of Au(x) clusters on a CeO2(111) surface.

Studying the structures of metal clusters on oxide supports is challenging due to their various structural possibilities. In the present work, a simple rule in which the number of Au atoms in different layers of Au(x) clusters is changed successively is used to systematically investigate the structures of Au(x) (x=1-10) clusters on stoichiometric and partially reduced CeO(2)(111) surface by DFT calculations. The calculations indicate that the adsorption energy of a single Au atom on the surface, the surface structure, as well as the Au-Au bond strength and arrangement play the key roles in determining Au(x) structures on CeO(2)(111). The most stable Au(2) and Au(3) clusters on CeO(2)(111) are 2D vertical structures, while the most stable structures of Au(x) clusters (x>3) are generally 3D structures, except for Au(7). The 3D structures of large Au(x) clusters in which the Au number in the bottom layer does not exceed that in the top layer are not stable. The differences between Au(x) on CeO(2)(111) and Mg(100) were also studied. The stabilizing effect of surface oxygen vacancies on Au(x) cluster structures depends on the size of Au(x) cluster and the relative positions of Au(x) cluster and oxygen vacancy. The present work will be helpful in improving the understanding of metal cluster structures on oxide supports.

A density functional theory study of the CH(2)I(2) reaction on Ag(111): Thermodynamics, kinetics, and electronic structures.

Density functional theory calculation was performed to study the adsorption and reaction of CH(2)I(2) on Ag(111). Thermodynamically favorable reactions of CH(2)I(2) on Ag(111) are C-I bond ruptures and CH(2) coupling to form ethylene. The energy barriers for the C-I bond ruptures of chemisorbed CH(2)I(2) on Ag(111) are 0.43-0.48 eV, whereas the activation energy for the C-H bond rupture of chemisorbed CH(2) on Ag(111) is 1.76 eV. The coupling reaction barrier of neighboring chemisorbed CH(2) to form C(2)H(4) on Ag(111) was much less than those of the C-I bond ruptures of CH(2)I(2)(a) and the migration of chemisorbed CH(2) on Ag(111). The adsorption behaviors of different surface species on Ag(111) were well explained in terms of the charge density difference.