C. M. Lee scite author profile

The undecapeptide substance P is a putative neurotransmitter in the mammalian central nervous system (CNS), and may be associated with pain fibres in the spinal cord. Radiolabelled derivatives of other neuropeptides have been used to demonstrate specific interactions with receptor sites on brain membranes, and this approach has now been explored with substance P. We have now prepared [4-3H-Phe8]-substance P and we find that it binds reversibly to a saturable population of sites in rat brain particulate fractions. Scatchard analysis of concentration-dependent saturation of binding indicates a single population of non-interacting sites with a high affinity (Kd=0.38 nM) and a low density (Bmax=27.2 fmol per mg protein). Kinetic analyses indicate an apparent dissociation equilibrium constant of 0.46 nM. A variety of neurotransmitter amines and amino acids, and other peptides do not compete at the substance P sites, but structurally related peptides or shorter C-terminal fragments of substance P are active. The rank order of potency of these substance P-related peptides agrees with that reported for their effects in depolarizing spinal cord neurones. The regional distribution of the specific binding sites for 3H-substance P parallels that of substance P immunoreactivity, being high in the hypothalamus and low in the cerebellum and cerebral cortex. The characteristics of the 3H-substance P binding sites are consistent with those expected for substance P receptors.

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Spin transport parameters of NbN thin films characterized by spin pumping experiments

Rogdakis

Sud

Amado

et al. 2019

Phys. Rev. Materials

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We present measurements of ferromagnetic-resonance -driven spin pumping and inverse spin-Hall effect in NbN/Y3Fe5O12 (YIG) bilayers. A clear enhancement of the (effective) Gilbert damping constant of the thin-film YIG was observed due to the presence of the NbN spin sink.By varying the NbN thickness and employing spin-diffusion theory, we have estimated the room temperature values of the spin diffusion length and the spin Hall angle in NbN to be 14 nm and -1.1×10 -2 , respectively. Furthermore, we have determined the spin-mixing conductance of the NbN/YIG interface to be 10 nm -2 . The experimental quantification of these spin transport parameters is an important step towards the development of superconducting spintronic devices involving NbN thin films.

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C. M. Lee

Specific binding of 3H-substance P to rat brain membranes

Spin transport parameters of NbN thin films characterized by spin pumping experiments

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