Temporally and spectrally multiplexed single photon source using quantum feedback control for scalable photonic quantum technologies

Current proposals for scalable photonic quantum technologies require on-demand sources of indistinguishable single photons with very high efficiency (having unheralded loss below $1\%$). Even with recent progress in the field there is still a significant gap between the requirements and state of the art performance. Here, we propose an on-chip source of multiplexed, heralded photons. Using quantum feedback control on a photon storage cavity with an optimized driving protocol, we estimate an on-demand efficiency of $99\%$ and unheralded loss of order $1\%$, assuming high efficiency detectors and intrinsic cavity quality factors of order $10^8$. We further explain how temporal- and frequency-multiplexing can be used in parallel to significantly reduce device requirements if single photon frequency conversion is possible with efficiency in the same range of $99\%$

Polyacrylate adsorbents for the selective adsorption of cholesterol-rich lipoproteins from plasma or blood

Polyacrylate (PAA) adsorbents selectively bind low density lipoproteins (LDL) from human plasma and blood, whereas very low density lipoproteins (VLDL) are only minimally adsorbed. The adsorption of cholesterol-rich lipoproteins to PAA adsorbents is related to the molecular weight (mw) of the polyanion ligand. Ca++ and Mg++ inhibit the binding of LDL to PAA adsorbents. The chemical composition of the organic hardgels of the adsorbents does not have an influence on adsorption. The selective adsorption of LDL to PAA adsorbents can be explained to result from their low negative surface charge density and the specific colloid-chemical properties of the surface-bound PAA, which do not prevent LDL from binding to charge-like domains of the ligand. By contrast, VLDL and high density lipoproteins (HDL) are repelled from the adsorbents due to their higher negative surface charge density

IDENTIFICATION OF A NON-CLASSICAL GLUCOCORTICOID-RESPONSIVE ELEMENT IN THE 5'-FLANKING REGION OF THE CHICKEN GROWTH HORMONE GENE

Growth hormone (GH) effects growth and contributes to a lean phenotype in broiler chickens. GH secretion by the anterior pituitary begins on embryonic day (e) 14, concomitantly with a rise in adrenal glucocorticoids (GC) or corticosterone (CORT) secretion. CORT treatment of chicken embryonic pituitary (CEP) cells induces GH secretion prematurely. GC induction of the GH gene requires on-going protein synthesis or an intermediary protein, but the gene lacks a classical GC-response element. We hypothesized that a GC-responsive intermediary protein is necessary for the CORT induced increase in GH. Characterization of the upstream region of the gene may help identify such a protein. To this end, a fragment of the GH gene (-1727/+48) was cloned into a luciferase reporter and characterized in e11 CEP cells. CORT treatment increased luciferase activity and mRNA. Inclusion of CHX blocked CORT induction of luciferase mRNA. Through deletion analysis, we found that a GC-responsive region (GCRR) is located at -1045 to -954. By defining the GC-responsive region and cis-acting elements located within, trans-acting proteins involved in GC induction of the GH gene may be identified. The GCRR is CORT-responsive in either orientation, but it is context-dependent. Potential transcription factor motifs in the GCRR include ETS-1 and a degenerate GRE (GREF). Nuclear proteins bound to a GCRR probe in a CORT-regulated manner and unlabeled competitor DNA competed off binding. Mutation of the central portion of the DNA probe resulted in a significant decrease in protein binding. Mutation of the ETS-1 site or GREF site in the -1045/+48 GH construct resulted in ablation of luciferase activity. ETS-1 and GR are associated with the endogenous gene under basal and 1.5 h CORT-treated conditions, while GR recruitment increased after CORT treatment. GC regulation of the GH gene during chicken embryonic development requires cis-acting elements located 1 kb upstream from the transcription start site and includes recruitment of ETS-1 and GR. This is the first study to demonstrate involvement of ETS-1 in GC regulation of the GH gene during embryonic development. Characterization of GC regulation of the GH gene during embryonic development enhances our understanding of growth regulation in vertebrates