Direct Observation of Li‐Ion Transport in Electrodes under Nonequilibrium Conditions Using Neutron Depth Profiling

One of the key challenges of Li‐ion electrodes is enhancement of (dis)charge rates. This is severely hindered by the absence of a technique that allows direct and nondestructive observation of lithium ions in operating batteries. Direct observation of the Li‐ion concentration profiles using operando neutron depth profiling reveals that the rate‐limiting step is depended not only on the electrode morphology but also on the cycling rate itself. In the LiFePO₄ electrodes phase nucleation limits the charge transport at the lowest cycling rates, whereas electronic conductivity is rate limiting at intermediate rates, and only at the highest rates ionic transport through the electrode is rate limiting. These novel insights into electrode kinetics are imperative for the improvement of Li‐ion batteries and show the large value of in situ NDP in Li‐ion battery research and development.     

The Effect of Antisite Disorder and Particle Size on Li Intercalation Kinetics in Monoclinic LiMnBO3

In materials containing 1D lithium diffusion channels, cation disorder can strongly affect lithium intercalation processes. This work presents a model to explain the unusual transport properties of monoclinic LiMnBO₃, a material determined by scanning electron microscopy and synchrotron X‐ray diffraction to contain a wide particle size distribution and Mn/Li antisite disorder. First‐principles calculations indicate that Mn occupying Li sites obstruct the 1D lithium diffusion channel along the [001] direction. While channel blockage by the antisites significantly lowers Li mobility in large particles, Li kinetics in small particles and particle surfaces are found to be less sensitive to the presence of antisite disorder. Thus, in an electrode containing a large particle size distribution, smaller particles have higher Li mobility, and the measured Li diffusivity as determined by potentiostatic intermittent titration test varies as a function of particle size. The Li capacity in monoclinic LiMnBO₃ is kinetically controlled by the fraction of large particles with antisite disorder, but is not intrinsically limited. These results strongly suggest that particle nanosizing will significantly enhance the electrochemical performance of LiMnBO₃.     

Proteomic changes in the brain of the western painted turtle (Chrysemys picta bellii) during exposure to anoxia

During anoxia, overall protein synthesis is almost undetectable in the brain of the western painted turtle. The aim of this investigation was to address the question of whether there are alterations to specific proteins by comparing the normoxic and anoxic brain proteomes. Reductions in creatine kinase, hexokinase, glyceraldehyde‐3‐phosphate dehydrogenase, and pyruvate kinase reflected the reduced production of adenosine triphosphate (ATP) during anoxia while the reduction in transitional endoplasmic reticulum ATPase reflected the conservation of ATP or possibly a decrease in intracellular Ca²⁺. In terms of neural protection programed cell death 6 interacting protein (PDCD6IP; a protein associated with apoptosis), dihydropyrimidinase‐like protein, t‐complex protein, and guanine nucleotide protein G_(o) subunit alpha (G_o alpha; proteins associated with neural degradation and impaired cognitive function) also declined. A decline in actin, gelsolin, and PDCD6IP, together with an increase in tubulin, also provided evidence for the induction of a neurological repair response. Although these proteomic alterations show some similarities with the crucian carp (another anoxia‐tolerant species), there are species‐specific responses, which supports the theory of no single strategy for anoxia tolerance. These findings also suggest the anoxic turtle brain could be an etiological model for investigating mammalian hypoxic damage and clinical neurological disorders.     

A Novel Phase of Li15Si4 Synthesized under Pressure

Li₁₅Si₄, the only crystalline phase that forms during lithiation of the Si anode in lithium‐ion batteries, is found to undergo a structural transition to a new phase at 7 GPa. Despite the large unit cell of Li₁₅Si₄ (152 atoms in the unit cell), ab initio evolutionary metadynamics (using the USPEX code) successfully predicts the atomic structure of this new phase (β‐Li₁₅Si₄), which has an orthorhombic structure with an Fdd2 space group. In the new β‐Li₁₅Si₄ phase Si atoms are isolated by Li atoms analogous to the original cubic phase (α‐Li₁₅Si₄), whereas the atomic packing is more efficient owing to the higher Si? Li coordination number and shorter Si? Li, Li? Li bonds. β‐Li₁₅Si₄ has substantially larger elastic moduli compared with α‐Li₁₅Si₄, and has a good electrical conductivity. As a result, β‐Li₁₅Si₄ has superior resistance to deformation and fracture under stress. The theoretical volume expansion of Si would decrease 25% if it transforms to β‐Li₁₅Si₄, instead of α‐Li₁₅Si₄, during lithiation. Moreover, β‐Li₁₅Si₄ can be recovered back to ambient pressure, providing opportunities to further investigate its properties and potential applications.     

基于方证相关探讨茵陈蒿汤调控库普弗细胞功能及MAPK通路抗肝纤维化的作用机制

目的：基于前期茵陈蒿汤类方抗肝硬化的方证病理基础结果,围绕“方-证相关”的学术内涵,提出了“方证相关时,方剂对机体基因的调控遵循‘无差错修复’原则”的假说;并探讨茵陈蒿汤对DMN诱导大鼠肝纤维化形成阶段肝组织库普弗细胞（Kupffer Cells,KCs）相关基因表达及对丝裂原活化蛋白激酶（MAPK）通路的影响。方法：采用wistar大鼠,于每周前3天连续腹腔注射0．5％二甲基亚硝胺（Dimethylnitrosamine,DMN）制备大鼠肝纤维化模型,2周末取模型组6只做动态观察。第3周初开始,在持续造模的同时给予茵陈蒿汤干预治疗到4周末,正常组与模型对照组给予等量生理盐水。4周末在3％戊巴比妥钠腹腔注射麻醉情况下,杀鼠取材,检测肝功能、肝组织病理、肝组织羟脯氨酸含量、胶原半定量,并采用基因芯片检测分析茵陈蒿汤对模型大鼠肝组织基因表达谱的影响。结果：与正常组比较,造模4周大鼠血清肝功能水平明显升高（P＜0．01）;病理观察肝组织炎细胞显著浸润,胶原显著沉积（P＜0．01）,肝组织白介素1（IL-1 b）、Cd68、肿瘤坏死因子受体超家族成员14（Tnfrsf14）、肿瘤坏死因子受体超家族成员9（Tnfrsf9）、TNF受体超家族成员6（Fas）、Cd14、结缔组织生长因子（Ctgf）、Ⅰ型胶原α2（Col1 a2）、胰岛素样生长因子结合蛋白（Igfals）、胰岛素样生长因子1（Igf1）、胰岛素样生长因子结合蛋白1（Igfbp1）、基质金属蛋白酶12（Mmp12）、基质金属蛋白酶2（Mmp2）、基质金属蛋白酶23（Mmp23）、趋化因子配体21（Ccl21）、蛋白激酶Cβ（Prkcb）基因表达明显上调,MAPK通路被激活。经2周治疗后茵陈蒿汤能显著降低DMN诱导的大鼠血清肝功能水平,抑制组织炎细胞的浸润与坏死,胶原沉积,并下调了肝组织IL-1 b、Cd68、Tnfrsf14、Tn-frsf9、Fas、Cd14、Ctgf、Col1 a2、Igfals、Igf1、Igfbp1、Mmp12、Mmp2、Mmp23、Ccl21、Prkcb 基因的表达,抑制了MAPK通路的活化。通过全基因芯片的分析,在茵陈蒿汤干预治疗后基因表达得到了不同程度的修复。结论：验证了“方证相关时,方剂对机体基因的调控遵循‘无差错修复’原则”的假说;茵陈蒿汤显著抑制DMN 诱导肝纤维化形成,其机制可能是调控了KCs,抑制相关炎症因子的释放,同时可能参与调控MAPK通路,从而达到抗肝纤维化的作用。     

XPC: Going where no DNA damage sensor has gone before

XPC has long been considered instrumental in DNA damage recognition during global genome nucleotide excision repair (GG-NER). While this recognition is crucial for organismal health and survival, as XPC’s recognition of lesions stimulates global genomic repair, more recent lines of research have uncovered many new non-canonical pathways in which XPC plays a role, such as base excision repair (BER), chromatin remodeling, cell signaling, proteolytic degradation, and cellular viability. Since the first discovery of its yeast homolog, Rad4, the involvement of XPC in cellular regulation has expanded considerably. Indeed, our understanding appears to barely scratch the surface of the incredible potential influence of XPC on maintaining proper cellular function. Here, we first review the canonical role of XPC in lesion recognition and then explore the new world of XPC function.     

Cardiac telocytes are double positive for CD34/PDGFR‐α

Telocytes (TCs) are a distinct type of interstitial cells, which are featured with a small cellular body and long and thin elongations called telopodes (Tps). TCs have been widely identified in lots of tissues and organs including heart. Double staining for CD34/PDGFR‐β (Platelet‐derived growth factor receptor β) or CD34/Vimentin is considered to be critical for TC phenotyping. It has recently been proposed that CD34/PDGFR‐α (Platelet‐derived growth factor receptor α) is actually a specific marker for TCs including cardiac TCs although the direct evidence is still lacking. Here, we showed that cardiac TCs were double positive for CD34/PDGFR‐α in primary culture. CD34/PDGFR‐α positive cells (putative cardiac TCs) also existed in mice ventricle and human cardiac valves including mitral valve, tricuspid valve and aortic valve. Over 87% of cells in a TC‐enriched culture of rat cardiac interstitial cells were positive for PDGFR‐α, while CD34/PDGFR‐α double positive cells accounted for 30.25% of the whole cell population. We show that cardiac TCs are double positive for CD34/PDGFR‐α. Better understanding of the immunocytochemical phenotypes of cardiac TCs might help using cardiac TCs as a novel source in cardiac repair.