{"id":"W3004662929","doi":"10.1016/j.bpj.2019.11.1635","title":"A Computational Model of pH Dynamics within the Cleft of Conventional Neuronal Synapses","year":2020,"lang":"en","type":"article","venue":"Biophysical Journal","topic":"Neuroscience and Neuropharmacology Research","field":"Neuroscience","cited_by":1,"is_retracted":false,"has_abstract":false,"ca_institutions":"Dalhousie University","funders":"","keywords":"Neurotransmission; Synaptic cleft; Biophysics; Exocytosis; Synaptic vesicle; Neuroscience; Glutamate receptor; Chemistry; Neurotransmitter; Active zone; Biology; Biochemistry; Vesicle; Membrane; Central nervous system","routes":{"ca_aff":true,"ca_fund":false,"ca_venue":false,"about_ca":false,"invisible_to_affiliation_only":false},"retraction":null,"screen":{"n_in":0,"stratum":"aff_core","weight":5595.2375,"opus":{"tier":"OUT","genre":"empirical","about_ca":false,"confidence":"high","reason":"Computational model of synaptic cleft pH dynamics; a neuroscience question."},"gpt":{"tier":"OUT","genre":"empirical","about_ca":false,"confidence":"high","reason":"The work presents a computational model of synaptic pH dynamics."},"grok":{"tier":"OUT","genre":"empirical","about_ca":false,"confidence":"medium","reason":"Computational model of synaptic cleft pH is neuroscience domain research; empty abstract but title is unambiguous."}}}