Siderophore-Linked Ruthenium Catalysts for Targeted Allyl Ester Prodrug Activation within Bacterial Cells.

Due to rising resistance, new antibacterial strategies are needed, including methods for targeted antibiotic release. As targeting vectors, chelating molecules called siderophores that are released by bacteria to acquire iron have been investigated for conjugation to antibacterials, leading to the clinically approved drug cefiderocol. The use of small-molecule catalysts for prodrug activation within cells has shown promise in recent years, and here we investigate siderophore-linked ruthenium catalysts for the activation of antibacterial prodrugs within cells. Moxifloxacin-based prodrugs were synthesised, and their catalyst-mediated activation was demonstrated under anaerobic, biologically relevant conditions. In the absence of catalyst, decreased antibacterial activities were observed compared to moxifloxacin versus Escherichia coli K12 (BW25113). A series of siderophore-linked ruthenium catalysts were investigated for prodrug activation, all of which displayed a combinative antibacterial effect with the prodrug, whereas a representative example displayed little toxicity against mammalian cell lines. By employing complementary bacterial growth assays, conjugates containing siderophore units based on catechol and azotochelin were found to be most promising for intracellular prodrug activation.

Pilot Study: Cut the Cut-A Treatment Program for Adolescent Inpatients with Nonsuicidal Self-Injury.

Non-suicidal-self-injury (NSSI) in adolescents needing inpatient treatment is a serious health risk behaviour. NSSI-specific treatment programs for inpatients hardly exist. "Cut the Cut" (CTC) is a new treatment program in intervals, addressing this problem. Aim of this pilot-study was to evaluate acceptability and feasibility of CTC. 23 female inpatients (12 CTC, 11 control, aged 15-17; mean = 16.80, SD.70) engaging in NSSI were evaluated for service user satisfaction, frequency, and severity of NSSI at T1 (admission), T2 (discharge after interval 1, CTC-group) and T3 (discharge). A qualitative interview was performed at T3. Significant improvement in NSSI-frequency was given (T1-T3: CTC p = 0.010; control p = 0.038). Severity of NSSI reduced slightly (mild NSSI: CTC p = 0.022, control p = 0.087; severe NSSI: CTC p = 0.111, control p = 0.066). Satisfaction of parents (T3 mean 28.38) and adolescents (T3 mean 26.11) in CTC was rated high. CTC is a feasible treatment option for inpatients engaging in NSSI. Further studies over time are needed.Trial registration Number DRKS00016762, 05.03.2019, retrospectively registered.

FAConstructor: an interactive tool for geometric modeling of nerve fiber architectures in the brain.

PURPOSE: The technique 3D polarized light imaging (3D-PLI) allows to reconstruct nerve fiber orientations of postmortem brains with ultra-high resolution. To better understand the physical principles behind 3D-PLI and improve the accuracy and reliability of the reconstructed fiber orientations, numerical simulations are employed which use synthetic nerve fiber models as input. As the generation of fiber models can be challenging and very time-consuming, we have developed the open source FAConstructor tool which enables a fast and efficient generation of synthetic fiber models for 3D-PLI simulations. METHODS: The program was developed as an interactive tool, allowing the user to define fiber pathways with interpolation methods or parametric functions and providing visual feedback. RESULTS: Performance tests showed that most processes scale almost linearly with the amount of fiber points in FAConstructor. Fiber models consisting of < 1.6 million data points retain a frame rate of more than 30 frames per second, which guarantees a stable and fluent workflow. The applicability of FAConstructor was demonstrated on a well-defined fiber model (Fiber Cup phantom) for two different simulation approaches, reproducing effects known from 3D-PLI measurements. CONCLUSION: We have implemented a user-friendly and efficient tool that enables an interactive and fast generation of synthetic nerve fiber configurations for 3D-PLI simulations. Already existing fiber models can easily be modified, allowing to simulate many different fiber models in a reasonable amount of time.

Receptor density pattern confirms and enhances the anatomic-functional features of the macaque superior parietal lobule areas.

The macaque monkey superior parietal lobule (SPL) is part of a neuronal network involved in the integration of information from visual and somatosensory cortical areas for execution of reaching and grasping movements. We applied quantitative in vitro receptor autoradiography to analyse the distribution patterns of 15 different receptors for glutamate, GABA, acetylcholine, serotonin, dopamine, and adenosine in the SPL of three adult male Macaca fascicularis monkeys. For each area, mean (averaged over all cortical layers) receptor densities were visualized as a receptor fingerprint of that area. Multivariate analyses were conducted to detect clusters of areas according to the degree of (dis)similarity of their receptor organization. Differences in regional and laminar receptor distributions confirm the location and extent of areas V6, V6Av, V6Ad, PEc, PEci, and PGm as found in cytoarchitectonic and functional studies, but also enable the definition of three subdivisions within area PE. Receptor densities are higher in supra- than in infragranular layers, with the exception of kainate, M2, and adenosine receptors. Glutamate and GABAergic receptors are the most expressed in all areas analysed. Hierarchical cluster analyses demonstrate that SPL areas are organized in two groups, an organization that corresponds to the visual or sensory-motor characteristics of those areas. Finally, based on present results and in the framework of our current understanding of the structural and functional organization of the primate SPL, we propose a novel pattern of homologies between human and macaque SPL areas.

Derivation of Fiber Orientations From Oblique Views Through Human Brain Sections in 3D-Polarized Light Imaging.

3D-Polarized Light Imaging (3D-PLI) enables high-resolution three-dimensional mapping of the nerve fiber architecture in unstained histological brain sections based on the intrinsic birefringence of myelinated nerve fibers. The interpretation of the measured birefringent signals comes with conjointly measured information about the local fiber birefringence strength and the fiber orientation. In this study, we present a novel approach to disentangle both parameters from each other based on a weighted least squares routine (ROFL) applied to oblique polarimetric 3D-PLI measurements. This approach was compared to a previously described analytical method on simulated and experimental data obtained from a post mortem human brain. Analysis of the simulations revealed in case of ROFL a distinctly increased level of confidence to determine steep and flat fiber orientations with respect to the brain sectioning plane. Based on analysis of histological sections of a human brain dataset, it was demonstrated that ROFL provides a coherent characterization of cortical, subcortical, and white matter regions in terms of fiber orientation and birefringence strength, within and across sections. Oblique measurements combined with ROFL analysis opens up new ways to determine physical brain tissue properties by means of 3D-PLI microscopy.

3D Reconstructed Cyto-, Muscarinic M2 Receptor, and Fiber Architecture of the Rat Brain Registered to the Waxholm Space Atlas.

High-resolution multiscale and multimodal 3D models of the brain are essential tools to understand its complex structural and functional organization. Neuroimaging techniques addressing different aspects of brain organization should be integrated in a reference space to enable topographically correct alignment and subsequent analysis of the various datasets and their modalities. The Waxholm Space (http://software.incf.org/software/waxholm-space) is a publicly available 3D coordinate-based standard reference space for the mapping and registration of neuroanatomical data in rodent brains. This paper provides a newly developed pipeline combining imaging and reconstruction steps with a novel registration strategy to integrate new neuroimaging modalities into the Waxholm Space atlas. As a proof of principle, we incorporated large scale high-resolution cyto-, muscarinic M2 receptor, and fiber architectonic images of rat brains into the 3D digital MRI based atlas of the Sprague Dawley rat in Waxholm Space. We describe the whole workflow, from image acquisition to reconstruction and registration of these three modalities into the Waxholm Space rat atlas. The registration of the brain sections into the atlas is performed by using both linear and non-linear transformations. The validity of the procedure is qualitatively demonstrated by visual inspection, and a quantitative evaluation is performed by measurement of the concordance between representative atlas-delineated regions and the same regions based on receptor or fiber architectonic data. This novel approach enables for the first time the generation of 3D reconstructed volumes of nerve fibers and fiber tracts, or of muscarinic M2 receptor density distributions, in an entire rat brain. Additionally, our pipeline facilitates the inclusion of further neuroimaging datasets, e.g., 3D reconstructed volumes of histochemical stainings or of the regional distributions of multiple other receptor types, into the Waxholm Space. Thereby, a multiscale and multimodal rat brain model was created in the Waxholm Space atlas of the rat brain. Since the registration of these multimodal high-resolution datasets into the same coordinate system is an indispensable requisite for multi-parameter analyses, this approach enables combined studies on receptor and cell distributions as well as fiber densities in the same anatomical structures at microscopic scales for the first time.

Impact of priming on the response of neutrophils to human neutrophil alloantigen-3a antibodies.

BACKGROUND: Human neutrophil alloantigen-3a (HNA-3a) antibodies can induce transfusion-related acute lung injury (TRALI). The severity of TRALI varies largely among the affected patients. Severe comorbidity seems to increase the susceptibility for TRALI, potentially by priming of neutrophils. Thus, the impact of neutrophil priming on HNA-3a antibody-mediated neutrophil aggregation and CD11b surface expression was investigated. STUDY DESIGN AND METHODS: Neutrophils were primed using formyl-methionyl-leucyl-phenylalanine (fMLP) or bacterial lipopolysaccharide (LPS). Granulocyte aggregation and CD11b surface expression were evaluated by the granulocyte agglutination test and by flow cytometry (FC), respectively. Priming-induced changes in the surface expression of choline transporter-like protein 2 (CTL2) and the CTL2 mRNA expression were assessed by FC and quantitative real-time polymerase chain reaction, respectively. RESULTS: Priming of neutrophils lowered the amount of HNA-3a antibodies required for inducing granulocyte aggregation in a dose-dependent manner by 50% to 75%. The priming agent concentration necessary for this response differed between donors. Priming slightly enhanced binding of HNA-3a antibodies to neutrophils. However, CTL2 de novo synthesis was not induced after priming with LPS, indicating that increased HNA-3a antibody binding was likely caused by translocation of intracellular CTL2 to the surface or by increased affinity of HNA-3a antibodies to CTL2. HNA-3a antibodies influenced CD11b surface expression on neutrophils only marginally, which was also not potentiated by priming with fMLP or LPS. CONCLUSION: This study provides experimental evidence supporting the "threshold model" of TRALI. Priming of neutrophils with fMLP or LPS increases their aggregation response to HNA-3a antibodies by lowering the required antibody amount.

Human neutrophil antigen-3a antibodies induce neutrophil aggregation in a plasma-free medium.

BACKGROUND: Antibodies against the human neutrophil alloantigen-3a (HNA-3a) are involved in severe cases of transfusion-related acute lung injury (TRALI), but the susceptibility of patients towards HNA-3a antibody differs largely. HNA-3a antibodies induce granulocyte aggregation. However, it is unresolved whether plasma proteins are required for granulocyte aggregation. MATERIALS AND METHODS: We investigated whether HNA-3a-antibody-induced aggregation of polymorphonuclear cells is dependent on plasma factors by using and modifying the granulocyte agglutination test (GAT). RESULTS: Polymorphonuclear cells homozygous for HNA-3a did not aggregate when incubated with HNA-3a antibodies in a plasma-protein-free GAT setup. When the GAT was performed using polymorphonuclear cells re-suspended in phosphate-buffered saline containing proteins, HNA-3-mediated aggregation was observed. Moreover, using Tween® 20 for blocking the plates, reconstituted the granulocyte aggregation in a protein-free medium. This indicates that granulocyte aggregation probably occurs by direct granulocyte-granulocyte interaction(s) or is mediated by substances released by neutrophils after activation. DISCUSSION: Granulocyte aggregation induced by HNA-3a antibodies does not require human plasma proteins. Interindividual variability in the response to HNA-3a antibodies does not depend on differences in patient's plasma proteins.