Podoplanin is known as a lymphatic marker because its expression is detected in lymphatic but not vascular endothelium. Podoplanin is also expressed in several normal tissues including osteocytes or osteoblasts. A systematic examination of the podoplanin expression was conducted in normal skeletal tissues and some bone tumor cell lines, and the diagnostic value determined in primary bone tumors. Podoplanin mRNA was expressed at a high level in bone marrow tissue and cartilage, and was upregulated with differentiation to osteoblasts in bone marrow cells. Strong podoplanin expression was seen in osteocytes, chondrocytes, and osteoblasts on immunohistochemistry. Podoplanin mRNA was expressed at a high level in several osteosarcoma and chondrosarcoma cell lines, whereas podoplanin was expressed at a low level in a Ewing's/primitive neuroectodermal tumor cell line. In the clinical samples, osteosarcomas (22/26) expressed podoplanin at various levels. In small cell osteosarcomas (2/2), podoplanin was expressed strongly, although the tissue samples included few diagnostic osteoids. Chondrosarcomas (10/10) expressed podoplanin strongly, and chondroblastomas (5/5) expressed podoplanin moderately, while podoplanin was absent or expressed at low levels in Ewing's sarcomas (0/5), chordomas (0/6) and giant cell tumors of bone (1/7). Therefore, podoplanin may be a sensitive immunohistochemical marker of osteogenic and chondrogenic bone tumors.
In
contrast to the energy-extensive Haber–Bosch process,
green production of ammonia (NH3) at ambient conditions
remains as one of the main goals of the 21st century. In this work,
we systematically studied single and double transition metal atoms
(Fe, Co, Mo, Ru) anchored on graphyne (GY) for nitrogen (N2) reduction by means of density functional theory (DFT). We demonstrated
that Ru dimer anchored on two-dimensional (2D) GY exhibits superior
catalytic activity for nitrogen reduction via an enzymatic pathway
with the maximum free energy change (ΔG) of
0.43 eV. Our findings propose highly reactive catalytic materials
for efficient N2 reduction while highlighting the importance
of double-atom catalysts for nitrogen reduction reaction (NRR).
Effect of metal nature on reductive amination was investigated with biomass‐based furfural as a typical substrate. Among the tested heterogeneous metal catalysts, cobalt proved to be the most effective metal for the synthesis of the corresponding primary amine. Under a relatively mild reaction condition, 98.9 % yield of furfurylamine was obtained over Raney Co and it can be reused more than eight times without a significant decrease in the catalytic performance. By extensively studying the catalytic pathways and reaction mechanism, it is found that the selectivity to primary amine and secondary amine was governed by the relative rate of hydrogenolysis and hydrogenation of the Schiff base intermediate. The superiority of Raney Co in furfurylamine synthesis can be ascribed to its high efficiency on hydrogenolysis of the Schiff base intermediate and its low performance in the hydrogenation of the Schiff base, carbonyl group and furan ring. Furthermore, ammonia greatly promoted the catalytic hydrogenolysis of the Schiff base intermediate over Raney Co without clear deactivation of the metal active sites.
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