Stable hydrogen-bonded organic frameworks and their photo-and electro-responses

Hydrogen-bonded organic frameworks(HOFs)are a recent class of porous materials that have garnered considerable research interest owing to their distinctive characteristics.HOFs can be constructed through judicious selection of H-bonding motifs,which are further enforced by other weak intermolecular interactions such asπ–πstacking,van der Waals forces,and framework interpenetration.Taking advantage of these interactions,we can expand the functional field of HOFs by introducing active molecules.Recently,researchers have made substantial advancements in using HOFs for chemical sensing,catalysis,proton conduction,biological applications,and others.The low bonding energy of H-bonds allows for precise control over the concentration of ligands in solvents,forming diverse HOF structures.These varied structures offer significant advantages for producing HOFs with photo-responsive and electro-responsive properties.However,the presence of H-bonds in HOFs results in their inherent lower stability compared to metal-organic frameworks(MOFs)and covalent-organic frameworks(COFs)formed via coordination and covalent bonds,respectively.As a result,the pursuit of stable and innovative HOF materials with novel functional sites remains an ongoing challenge.This review provides an overview of recent research progress in the development of new strategies for stable HOF synthesis and applications of HOFs with stimuli-responsive properties.We first classified all synthetic methods reported to date and discussed the stable HOFs synthesized,as well as their unique properties and applications.In addition,we summarized the applications of HOFs utilizing their synergistic responses to external stimuli,including photo,electrical,pressure,and chemical stimuli.We systematically reviewed stable HOF synthesis and applications,which may lead to a deeper understanding of the structure–activity relationship for these materials and guide future HOF design.

颞叶癫痫异常神经环路分析(英文)

OBJECTIVE Temporal lobe epilepsy(TLE) is one of the most common types of human epilepsy,and they are often resistant to current treatments. METHODS By using optogenetic,electrophysiological,imaging and pharmacology strategies,we aimed toinvestigate the underlying circuit mechanism of TLE and tried to developthe novel and efficient approach to control epilepsy. RESULTS(1) Deep brain stimulation,especially low frequency stimulation,targeted the epileptic focus and the areas outside of the focus(critical regions for seizure spread),such as entorhinal cortex or subiculum,reduced seizure severity in TLE. Its anti-epileptic effect is time-window dependent and polarity dependent,which shows a promising strategy for treating epileptic seizures.(2) Using an optogenetic strategy,we demonstrated that excitatory projection from entorhinal cortex to hippocampus instructs the brain-stimulation treatments of epilepsy.(3) Our data from both the clinical and experimental studies further demonstrated that a disinhibitory GABAergic neuron-mediated microcircuit in the subiculum contributes to secondary generalized seizures in TLE.(4) Finally,based on abnormal synchronization of the electrical activity in epileptic circuit,we developed electro-responsive hydrogel nanoparticles modified with angiopep-2to facilitate the delivery of the antiepileptic drug phenytoin sodium,which greatly improves the therapeutic index. CONCLUSION Our findings may update the current view of epileptic neuronal networks and suggest possible promising ways for epilepsy treatment.

Modulation of abnormal neuronal circuit in temporal lobe epilepsy

OBJECTIVE Temporal lobe epilepsy(TLE)is one of the most common types of human epilepsy,and they are often resistant to current treatments.METHODS By using optogenetic,electrophysiological,imaging and pharmacology strategies,we aimed toinvestigate the underlying circuit mechanism of TLE and tried to developthe novel and efficient approach to control epilepsy.RESULTS(1)Using micro PET and multichannel EEG recording,we found an abnormal neural network,characterized by early hypometabolism and after discharge spread,during the epileptogenensis of TLE.(2)Deep brain stimulation,especially low frequency stimulation,targeted the epileptic focus and the areas outside of the focus(critical regions for seizure spread),such as the piriform cortex,cerebellum,entorhinal cortex or subiculum,reduced seizure severity in TLE.Its anti-epileptic effect is time-window dependent and polarity dependent,which shows a promising strategy for treating epileptic seizures.(3)Using an optogenetic strategy,we demonstrated that excitatory projection from entorhinal cortex to hippocampus instructs the brain-stimulation treatments of epilepsy.(4)Our data from both the clinical and experimental studies further demonstrated that a disinhibitory GABAergic neuronmediated microcircuit in the subiculum contributes to secondary generalized seizures in TLE.(5)Finally,based on abnormal synchronization of the electrical activity in epileptic circuit,we developed electroresponsive hydrogel nanoparticles modified with angiopep-2 to facilitate the delivery of the antiepileptic drug phenytoin sodium,which greatly improves the therapeutic index.CONCLUSION Our findings may update the current view of epileptic neuronal networks and suggest possible promising ways for epilepsy treatment.