Improving a Solid-State Qubit through an Engineered Mesoscopic Environment.

A controlled quantum system can alter its environment by feedback, leading to reduced-entropy states of the environment and to improved system coherence. Here, using a quantum-dot electron spin as a control and probe, we prepare the quantum-dot nuclei under the feedback of coherent population trapping and observe their evolution from a thermal to a reduced-entropy state, with the immediate consequence of extended qubit coherence. Via Ramsey interferometry on the electron spin, we directly access the nuclear distribution following its preparation and measure the emergence and decay of correlations within the nuclear ensemble. Under optimal feedback, the inhomogeneous dephasing time of the electron, T_{2}^{*}, is extended by an order of magnitude to 39 ns. Our results can be readily exploited in quantum information protocols utilizing spin-photon entanglement and represent a step towards creating quantum many-body states in a mesoscopic nuclear-spin ensemble.

Phase-Tuned Entangled State Generation between Distant Spin Qubits.

Quantum entanglement between distant qubits is an important feature of quantum networks. Distribution of entanglement over long distances can be enabled through coherently interfacing qubit pairs via photonic channels. Here, we report the realization of optically generated quantum entanglement between electron spin qubits confined in two distant semiconductor quantum dots. The protocol relies on spin-photon entanglement in the trionic Λ system and quantum erasure of the Raman-photon path information. The measurement of a single Raman photon is used to project the spin qubits into a joint quantum state with an interferometrically stabilized and tunable relative phase. We report an average Bell-state fidelity for |ψ^{(+)}⟩ and |ψ^{(-)}⟩ states of 61.6±2.3% and a record-high entanglement generation rate of 7.3 kHz between distant qubits.

Interfacing spins in an InGaAs quantum dot to a semiconductor waveguide circuit using emitted photons.

An in-plane spin-photon interface is essential for the integration of quantum dot spins with optical circuits. The optical dipole of a quantum dot lies in the plane and the spin is optically accessed via circularly polarized selection rules. Hence, a single waveguide, which can transport only one in-plane linear polarization component, cannot communicate the spin state between two points on a chip. To overcome this issue, we introduce a spin-photon interface based on two orthogonal waveguides, where the polarization emitted by a quantum dot is mapped to a path-encoded photon. We demonstrate operation by deducing the spin using the interference of in-plane photons. A second device directly maps right and left circular polarizations to antiparallel waveguides, surprising for a nonchiral structure but consistent with an off-center dot.

Population inversion in a single InGaAs quantum dot using the method of adiabatic rapid passage.

Preparation of a specific quantum state is a required step for a variety of proposed quantum applications. We report an experimental demonstration of optical quantum state inversion in a single semiconductor quantum dot using adiabatic rapid passage. This method is insensitive to variation in the optical coupling in contrast with earlier work based on Rabi oscillations. We show that when the pulse power exceeds a threshold for inversion, the final state is independent of power. This provides a new tool for preparing quantum states in semiconductor dots and has a wide range of potential uses.

A photonic atom probe coupling 3D atomic scale analysis with in situ photoluminescence spectroscopy.

Laser enhanced field evaporation of surface atoms in laser-assisted Atom Probe Tomography (APT) can simultaneously excite photoluminescence in semiconductor or insulating specimens. An atom probe equipped with appropriate focalization and collection optics has been coupled with an in situ micro-photoluminescence (µPL) bench that can be operated during APT analysis. The photonic atom probe instrument we have developed operates at frequencies up to 500 kHz and is controlled by 150 fs laser pulses tunable in energy in a large spectral range (spanning from deep UV to near IR). Micro-PL spectroscopy is performed using a 320 mm focal length spectrometer equipped with a CCD camera for time-integrated and with a streak camera for time-resolved acquisitions. An example of application of this instrument on a multi-quantum well oxide heterostructure sample illustrates the potential of this new generation of tomographic atom probes.

Quantum interface of an electron and a nuclear ensemble.

Coherent excitation of an ensemble of quantum objects underpins quantum many-body phenomena and offers the opportunity to realize a memory that stores quantum information. Thus far, a deterministic and coherent interface between a spin qubit and such an ensemble has remained elusive. In this study, we first used an electron to cool the mesoscopic nuclear spin ensemble of a semiconductor quantum dot to the nuclear sideband-resolved regime. We then implemented an all-optical approach to access individual quantized electronic-nuclear spin transitions. Lastly, we performed coherent optical rotations of a single collective nuclear spin excitation-a spin wave. These results constitute the building blocks of a dedicated local memory per quantum-dot spin qubit and promise a solid-state platform for quantum-state engineering of isolated many-body systems.

Quantum dot spin coherence governed by a strained nuclear environment.

The interaction between a confined electron and the nuclei of an optically active quantum dot provides a uniquely rich manifestation of the central spin problem. Coherent qubit control combines with an ultrafast spin-photon interface to make these confined spins attractive candidates for quantum optical networks. Reaching the full potential of spin coherence has been hindered by the lack of knowledge of the key irreversible environment dynamics. Through all-optical Hahn echo decoupling we now recover the intrinsic coherence time set by the interaction with the inhomogeneously strained nuclear bath. The high-frequency nuclear dynamics are directly imprinted on the electron spin coherence, resulting in a dramatic jump of coherence times from few tens of nanoseconds to the microsecond regime between 2 and 3 T magnetic field and an exponential decay of coherence at high fields. These results reveal spin coherence can be improved by applying large magnetic fields and reducing strain inhomogeneity.

Ear and vestibular symptoms in train operators after sudden air pressure changes in trains.

A healthy 31-year-old train operator presented to our occupational health clinic reporting ear aches, headaches, dizziness, unsteadiness and even slight tinnitus. These symptoms first appeared when the patient started operating from a new train cabin. He described a sudden pressure gradient, experienced on some parts of the trajectory, which might have caused these problems. Although the cabins were equipped with a pressure equalising device, this was usually switched off because of the device creating an uncomfortable feeling in the cabin. The literature describes sudden pressure gradients as possible factors for passenger discomfort.

Production, in Pichia pastoris, of a recombinant monomeric mapacalcine, a protein with anti-ischemic properties.

Mapacalcine is a small homodimeric protein of 19 kDa with 9 disulfide bridges extracted from the Cliona vastifica sponge (Red Sea). It selectively blocks a calcium current insensitive to most calcium blockers. Specific receptors for mapacalcine have been described in a variety of tissues such as brain, smooth muscle, liver, and kidney. Previous works achieved on hepatocytes and nervous cells demonstrated that this protein selectively blocks a calcium influx triggered by an ischemia/reperfusion (I/R) shock and efficiently protects cells from death after I/R. The aim of this work was to produce the recombinant mapacalcine in the yeast Pichia pastoris. Mass spectrometry, light scattering analysis and biological characterization demonstrated that the recombinant mapacalcine obtained was a monomeric form with 4 disulfide bridges which retains the biological activity of the natural protein.

Quantitative autoradiographic mapping in rat brain of the receptor of apamin, a polypeptide toxin specific for one class of Ca2+-dependent K+ channels.

The localization of the receptor for apamin, a specific toxin for one class of sensitive Ca2+-dependent K+ channel, was studied in rat brain using an in vitro autoradiographic technique. Radiolabeled monoiodoapamin binds specifically to rat brain sections with a high affinity (Kd = 25 pM) to a single class of sites. Autoradiograms demonstrated a very heterogeneous distribution of the apamin receptor throughout the brain. Very high grain densities were localized on the habenula, lateral septum, supraoptic and suprachiasmatic nuclei. Areas containing high levels of apamin binding sites included anterior olfactory nucleus, stratum oriens of hippocampus, pontine nuclei and granular layer of the cerebellar cortex and inferior olive. The thalamus, some nuclei of hypothalamus, hippocampus, tegmental area, red and oculomotor nuclei, vestibular nuclei and superior olive, among others, presented intermediate grain densities. In the other main areas, in particular basal ganglia, raphe, low to very low levels of apamin binding sites have been observed.

Characterization and partial purification from pheochromocytoma cells of an endogenous equivalent of scyllatoxin, a scorpion toxin which blocks small conductance Ca(2+)-activated K+ channels.

This work describes the partial purification of a heat-stable peptide which has the same properties as the scorpion toxin, scyllatoxin, a specific blocker of one class of Ca(2+)-activated K+ channels: (i) it competes with [125I]apamin for binding to the same site, (ii) like apamin and scyllatoxin, it blocks the after-potential hyperpolarization in skeletal muscle cells in culture, (iii) like apamin and scyllatoxin, it contracts guinea-pig taenia coli relaxed by epinephrine, (iv) it cross-reacts with antibodies raised against scyllatoxin but not with antibodies raised against apamin.

Distribution of mapacalcine receptors in the central nervous system of rat using the [125I]-labeled mapacalcine derivative.

Mapacalcine is a dimeric protein of Mr 19041 extracted from the marine sponge Cliona vastifica. Electrophysiological and pharmacological approaches have demonstrated that mapacalcine was blocking a calcium channel different from N-, L-, P-, T- or Q-type calcium channels on mouse intestinal smooth muscle. Recently a [125I]-labeled derivative of mapacalcine has been synthesized and characterized as a tool usable as a probe to investigate mapacalcine receptors. On rat brain membranes, it binds to its receptor with a K(d)=0.35 nM and a maximal binding capacity of 706 fmol/mg protein. We use here [125I]-mapacalcine to study the mapping of its receptors in the rat brain. Data obtained show a practically homogeneous labeling of the brain. Our experiments suggest that mapacalcine receptors are present on neuronal and glial cells. Interestingly, choroid plexus demonstrates a high density of mapacalcine receptors. These data would suggest that mapacalcine sensitive calcium channels could be involved in the control of calcium homeostasis of the cerebrospinal fluid.

Specific binding and pharmacological interactions of apamin, the neurotoxin from bee venom, with guinea pig colon.

This paper describes the interaction of apamin, the bee venom neurotoxin, with its receptor in the guinea pig colon. The pharmacological activity of the toxin was assayed by measuring its contracting effect on guinea pig colon preparations that had been previously relaxed by neurotensin. The IC50 value of apamin in this in vitro bioassay is 7 nM. These pharmacological data are compared to the binding properties of apamin to smooth muscle membranes prepared from guinea pig colon. The highly radiolabeled monoiododerivative of apamin binds to its colon receptor with a dissociation constant Kd* = 36 pM. The maximal binding capacity of colonic membranes is 30dfmol/mg of protein. The dissociation constant of the unmodified toxin is 23 pM. The difference between the toxin concentrations that produce half-maximal effects in the binding and pharmacological studies arises from the different experimental conditions used for the two assays.

[Strategy of quality of the application of the Huriet law in hospitals]. / Stratégie de la qualité dans l'application de la loi Huriet en milieu hospitalier.

Due to the "Huriet" law, the hospital pharmacist has new responsibilities in biomedical research. This article reports the activities of Pitié-Salpêtrière hospital. We also expose the organisation of drug dispensation and storage in our hospital pharmacy.

[The role of peptidic toxins in the pharmacological approach of the diversity of calcium channels]. / Contribution des toxines peptidiques à l'approche pharmacologique de la diversité des canaux calciques.

Peptidic toxins extracted from spider, marine snails or snakes venoms, have considerably helped the pharmacological characterization of calcium channels. They have successfully been used for calcium channels mapping. However, the actual situation remains unclear. Genetic investigations demonstrated the existence of a great number of types or sub-types of calcium channels. In recent year a large number of toxins have been purified. Many of these toxins have specific actions on calcium channels and have been used as powerful tools in pharmacological approaches of calcium channels. However the pharmacology of the calcium channels remains very limited, many of them are waiting for the discovery of pharmacological tools allowing their molecular approach in order to determinate their biological implications. In this paper we describe the different families of calcium channels and toxins that interact with these channels. We also recapitulate the "non defined" calcium channels i.e. calcium channel which does not correspond to a N, L, P/Q, R or T type channel and for which no effector are available. We report the discovery and characterization of mapacalcine, a toxin extracted for a marine sponge, as an example of an approach of an undefined calcium channels first characterized by electrophysiological techniques and for which a specific toxin has been purified allowing its pharmacological approach. We also state the possible role of calcium channel toxins in the domain of therapeutic applications.

Apamin: a specific toxin to study a class of Ca2+-dependent K+ channels.

Apamin is a bee venom neurotoxin of 18 amino-acids containing two disulfide bridges. Current clamp and voltage clamp experiments have shown that externally applied apamin blocks specifically at low concentration (0.1 microM) the Ca2+-dependent slow K+ conductance which mediates the long-lasting after-hyperpolarization in neuroblastoma cells and rat muscle cells in culture. The apamin-sensitive Ca2+-dependent slow K+ conductance is voltage-dependent and tetraethylammonium (TEA) insensitive. It is distinct from the high conductance Ca2+-dependent K+ channel revealed by patch clamp experiments. Biochemical characterization of the apamin receptor in rat striated muscle, neuroblastoma cells, rat synaptosomes, smooth muscles and hepatocytes was carried out with the use of a radiolabelled monoiodo-apamin derivative (125I-apamin) of high specific radioactivity (2 000 Ci/mmol). The dissociation constant of the apamin-receptor complex is between 15 and 60 pM for all tissue preparations. The density of binding sites is very low; it varied between 1 and 40 fmol/mg of protein. Radiation inactivation analysis indicates a molecular weight for the apamin receptor of 250 000 daltons whereas affinity labelling with 125I-apamin results in covalent labelling of a single polypeptide chain with a molecular weight of about 30 000 daltons. We conclude that the apamin-sensitive Ca2+-dependent K+ channel is probably a large oligomeric structure containing one subunit of 30 000 daltons.

125I-Labelled mapacalcine: a specific tool for a pharmacological approach to a receptor associated with a new calcium channel on mouse intestinal membranes.

Mapacalcine is a small protein (Mr=19041) composed of two homologous chains purified from the marine sponge Cliona vastifica. Recently, we demonstrated that it was able to specifically block a Ca2+ channel which could not be related to already described channels on mouse intestinal myocytes. This Ca2+ current was insensitive to the known peptidic and organic calcium channel blockers. Mapacalcine was ineffective on T-type and L-type Ca2+ currents present on rat portal vein myocytes [Morel, Drobecq, Sautière, Tartar, Mironneau, Qar, Lavie, and Hugues (1997) Mol. Pharmacol. 51, 1042-1052]. We report here the preparation and purification of a monoiodo-derivative of mapa-calcine which retains its biological properties. Binding parameters of mapacalcine to its receptors have been characterized on mouse intestinal membranes. It binds to its receptors with a Kd=0. 8 nM, and a maximal binding capacity of 171 fmol/mg of protein on membrane preparations. Our data show that we have prepared a tool that is usable for pharmacological studies of a receptor associated with a new type of calcium channel for which no ligand was available until now.

Properties of the apamin-sensitive Ca2+-activated K+ channel in PC12 pheochromocytoma cells which hyper-produce the apamin receptor.

Undifferentiated PC12 cell produce high levels of apamin receptors (measured with 125I-apamin) after 7 days in culture. These levels are at least 50 times higher than those found in other cellular types which are also known to have apamin receptors and apamin-sensitive Ca2+-activated K+ channels in their membranes. Treatment of undifferentiated PC12 cells with nerve growth factor maintains these cells in a state having a low level (10 times less after 7 days of culture) of apamin receptors. Ca2+ injection into PC12 cells with the calcium ionophore A23187 has been used to monitor the activity of the Ca2+-activated K+ channel following 86Rb+ efflux. A large component of this Ca2+-activated 86Rb+ efflux is inhibited by apamin. Half-maximum inhibition by apamin of both 86Rb+ efflux and 125I-apamin binding was observed at 240 pM apamin. Another component of 86Rb+ efflux is due to another type of Ca2+-activated K+ channel which is resistant to apamin and sensitive to tetraethylammonium. The Ca2+ channel activator Bay K8644 also triggers an apamin-sensitive Ca2+-dependent 86Rb+ efflux. Bay K8644 has been used to analyze the internal Ca2+ concentration dependence of the apamin-sensitive channel activity. Under normal conditions, the internal Ca2+ concentration is 109 +/- 17 nM, and the apamin-sensitive channel is not activated. The channel is fully activated at an internal Ca2+ concentration of 320 +/- 20 nM.