Die Verteilung der Blutgruppen unter geisteskranken Verbrechern

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The Cultural Heritage of “Black Stones” (Lapis Aequipondus/Martyrum) of Leopardi’s Child Home (Recanati,Italy)

A macroscopic lithological study and physical (hardness, size, weight) investigations, coupled with laser-induced breakdown spectroscopy (LIBS) and X-ray fluorescence (XRF) chemical analyses of three egg- and one pear-shaped polished black stones, exposed in the library of the child home of the famous poet Giacomo Leopardi, at Recanati (Italy), were carried out. They are characterized by different sizes: two with the same weight of 16.9 kg and the two smaller ones of 5.6 kg each, corresponding to multiples of standard roman weights (drachma and scrupulum). These features and the presence of some grooves on the rock artefacts, probably for grappling hooks, suggest an original use as counterweight for the four black stones herein classified as amphibole-bearing serpentinites whose lithologies are far away from Recanati (probably coming from geological outcrops in Tuscany). The four serpentinite stones closely match with the so-called Lapis Aequipondus used in antiquity by the Romans as counterweights. Due to the presence of lead rings or iron hooks in these stones, Lapis Aequipondus were also used for martyrdoms during the persecution of Christians in the Roman period, attached to the necks of martyrs that were then thrown in the wells or attached to the ankles of hanging bodies. This is the reason why these stones are also known as Lapis Martyrum, venerated with the relative martyrs, in several churches of Rome. The four black stones investigated probably arrived at Recanati from Rome after the middle of the 19th century. In the past, Christians also called Lapis Martyrum the “devil’s stones” (Lapis Diaboli). This could also be the reason for the popular belief that black stones cannot be touched by people, except those of the Leopardi dynasty. This work contributes to the cultural heritage of Leopardi’s child home, as the four black stones had never been investigated.     

Photoprotective and Antiaging Effects of a Standardized Red Orange (Citrus sinensis (L.) Osbeck) Extract in Asian and Caucasian Subjects: A Randomized,Double-Blind,Controlled Study

The increase in solar ultraviolet radiation (UVR) that reaches the Earth’s surface should make us reflect on the need to develop new approaches in protecting the skin from UVR exposure. The present study aims to evaluate the photoprotective and antiaging efficacy of a red orange extract (100 mg/day) in both Asian and Caucasian subjects. A randomized, double-blind, controlled study was carried out in 110 Asian and Caucasian subjects. Product efficacy was measured as follows: (1) the photoprotective effect was measured by the minimal erythema dose (MED) assessment; (2) the efficacy in decreasing the UVA+B-induced skin redness was measured by colorimetry; (3) the antioxidant efficacy was measured by the ferric-reducing antioxidant power (FRAP) and the malondialdehyde (MDA) assay; and (4) skin moisturization, skin elasticity, skin radiance, the intensity of melanin staining, transepidermal water loss (TEWL), and wrinkles were measured to assess the antiaging efficacy. The intake of the product for 56 days was effective in improving the skin reaction to UV exposure; in increasing the skin antioxidant capacity as well as in decreasing UVA-induced lipid peroxidation; in increasing the skin moisturization, skin elasticity, and skin radiance; and in decreasing TEWL, the intensity of melanin staining inside dark spots, and wrinkle depth. Our results suggest that the test product is effective in counteracting both the harmful effects of UVR exposure and aging signs.     

Platelet Activation Favours NOX2-Mediated Muscle Damage in Elite Athletes: The Role of Cocoa-Derived Polyphenols

Mechanisms of exercise-induced muscle injury with etiopathogenesis and its consequences have been described; however, the impact of different intensities of exercise on the mechanisms of muscular injury development is not well understood. The aim of this study was to exploit the relationship between platelet activation, oxidative stress and muscular injuries induced by physical exercise in elite football players compared to amateur athletes. Oxidant/antioxidant status, platelet activation and markers of muscle damage were evaluated in 23 elite football players and 23 amateur athletes. Compared to amateurs, elite football players showed lower antioxidant capacity and higher oxidative stress paralleled by increased platelet activation and muscle damage markers. Simple linear regression analysis showed that sNOX2-dp and H₂O₂, sCD40L and PDGF-bb were associated with a significant increase in muscle damage biomarkers. In vitro studies also showed that plasma obtained from elite athletes increased oxidative stress and muscle damage in human skeletal muscle myoblasts cell line compared to amateurs’ plasma, an effect blunted by the NOX2 inhibitor or by the cell treatment with cocoa-derived polyphenols. These results indicate that platelet activation increased muscular injuries induced by oxidative stress. Moreover, NOX2 inhibition and polyphenol extracts treatment positively modulates redox status and reduce exercise-induced muscular injury.     

A comparison between stereophotogrammetry and smartphone structured light technology for three-dimensional face scanning

ObjectivesTo compare three-dimensional facial scans obtained by stereophotogrammetry with two different applications for smartphone supporting the TrueDepth system, a structured light technology.Materials and MethodsFacial scans of 40 different subjects were acquired with three different systems. The 3dMDtrio Stereophotogrammetry System (3dMD, Atlanta, Ga) was compared with a smartphone (iPhone Xs; Apple, Cupertino, Calif) equipped with the Bellus3D Face Application (version 1.6.11; Bellus3D Inc, Campbell, Calif) or Capture (version 1.2.5; Standard Cyborg Inc, San Francisco, Calif). Times of image acquisition and elaboration were recorded. The surface-to-surface deviation and the distance between 18 landmarks from 3dMD reference images to those acquired with Bellus3D or Capture were measured.ResultsCapturing and processing times with the smartphone applications were considerably longer than with the 3dMD system. The surface-to-surface deviation analysis between the Bellus3D and 3dMD showed an overlap percentage of 80.01% ± 5.92% and 56.62% ± 7.65% within the ranges of 1 mm and 0.5 mm discrepancy, respectively. Images from Capture showed an overlap percentage of 81.40% ± 9.59% and 56.45% ± 11.62% within the ranges of 1 mm and 0.5 mm, respectively.ConclusionsThe face image acquisition with the 3dMD device is fast and accurate, but bulky and expensive. The new smartphone applications combined with the TrueDepth sensors show promising results. They need more accuracy from the operator and more compliance from the patient because of the increased acquisition time. Their greatest advantages are related to cost and portability.     

GABA-receptor stimulation enhances norepinephrine-induced polyphosphoinositide metabolism in rat hippocampal slices

The effect of gamma-aminobutyric acid (GABA)receptor stimulation on norepinephrine (NE)-induced metabolism of polyphosphoinositides (PIPs) was studied in rat hippocampal slices. Inositol phosphates (IPs), PIPs, and phosphatidic acid were measured. NE induced formation of IPs and phosphatidic acid in a dose-dependent manner with an EC50 of 4.5 microM. GABA, 3-aminopropanesulphonic acid (3APS) and muscimol did not affect PIPs breakdown, but they strongly increased (greater than 100%) PIPs metabolism induced by 1 microM NE. Their action was antagonized by bicuculline (10 microM). We discuss the implications of these findings in hippocampal neurotransmission.     

Incidence and spatial distribution of adult-onset primary malignant and other central nervous system tumors in Southern Sardinia,Italy

Neurological Sciences - To study for the first time the incidence of adult-onset CNS tumors in Southern Sardinia, Italy. Clinical records of patients > 18 years old who...     

Impaired Vagal Activity in Long-COVID-19 Patients

Long-COVID-19 refers to the signs and symptoms that continue or develop after the “acute COVID-19” phase. These patients have an increased risk of multiorgan dysfunction, readmission, and mortality. In Long-COVID-19 patients, it is possible to detect a persistent increase in D-Dimer, NT-ProBNP, and autonomic nervous system dysfunction. To verify the dysautonomia hypothesis in Long-COVID-19 patients, we studied heart rate variability using 12-lead 24-h ECG monitoring in 30 Long-COVID-19 patients and 20 No-COVID patients. Power spectral analysis of heart rate variability was lower in Long-COVID-19 patients both for total power (7.46 ± 0.5 vs. 8.08 ± 0.6; p < 0.0001; Cohens-d = 1.12) and for the VLF (6.84 ± 0.8 vs. 7.66 ± 0.6; p < 0.0001; Cohens-d = 1.16) and HF (4.65 ± 0.9 vs. 5.33 ± 0.9; p = 0.015; Cohens-d = 0.76) components. The LF/HF ratio was significantly higher in Long-COVID-19 patients (1.46 ± 0.27 vs. 1.23 ± 0.13; p = 0.001; Cohens-d = 1.09). On multivariable analysis, Long-COVID-19 is significantly correlated with D-dimer (standardized β-coefficient = 0.259), NT-ProBNP (standardized β-coefficient = 0.281), HF component of spectral analysis (standardized β-coefficient = 0.696), and LF/HF ratio (standardized β-coefficient = 0.820). Dysautonomia may explain the persistent symptoms in Long COVID-19 patients. The persistence of a procoagulative state and an elevated myocardial strain could explain vagal impairment in these patients. In Long-COVID-19 patients, impaired vagal activity, persistent increases of NT-ProBNP, and a prothrombotic state require careful monitoring and appropriate intervention.     

Cardiac sympathetic-vagal activity initiates a functional brain–body response to emotional arousal

A century-long debate on bodily states and emotions persists. While the involvement of bodily activity in emotion physiology is widely recognized, the specificity and causal role of such activity related to brain dynamics has not yet been demonstrated. We hypothesize that the peripheral neural control on cardiovascular activity prompts and sustains brain dynamics during an emotional experience, so these afferent inputs are processed by the brain by triggering a concurrent efferent information transfer to the body. To this end, we investigated the functional brain–heart interplay under emotion elicitation in publicly available data from 62 healthy subjects using a computational model based on synthetic data generation of electroencephalography and electrocardiography signals. Our findings show that sympathovagal activity plays a leading and causal role in initiating the emotional response, in which ascending modulations from vagal activity precede neural dynamics and correlate to the reported level of arousal. The subsequent dynamic interplay observed between the central and autonomic nervous systems sustains the processing of emotional arousal. These findings should be particularly revealing for the psychophysiology and neuroscience of emotions.

“What Is an Emotion?” by William James (1), published more than a century ago, started the scientific debate on the nature of emotions. However, a shared and definitive theory of emotions is not in place yet, and the very definition of emotions and their nature is still a matter of debate. While more “classical” theories point to emotions as “the functional states of the brain that provide causal explanations of certain complex behaviors—like evading a predator or attacking prey” (2), other theories suggest how they are constructions of the world, not reactions to it (3). Namely, emotions are internal states constructed on the basis of previous experiences as predictive schemes to react to external stimuli.The role of bodily activity in emotions is often questioned. Despite the vast literature showing bodily correlates with emotions, a long-lasting debate about the relationship between bodily states and emotions persists (4). For instance, a feeling is defined as the subjective metarepresentation and labeling of physiological changes (such as an increase in heart rate, the increase of blood pressure, or changes in peristalsis) (5) that are strictly related to the body state on the one hand and to emotions on the other. To this extent, emotions are complex psychological phenomena in which feelings are interpreted and labeled. In a particular psychopathological condition known as alexithymia, individuals experience difficulties in experiencing and understanding emotions to various degrees (6). Indeed, some of these patients can perceive the physical changes connected to a feeling but are unable to label it as emotion, so that emotional experience is described only as its physical counterpart [e.g., described an experience as “I have my heart beating too fast” instead of “I’m fearful” (7)]. From a biological point of view the way in which physical changes become feelings and emotions is based on the interplay between the central and the autonomic nervous systems.The central nervous system (CNS) communicates with the autonomic nervous system (ANS) through interoceptive neural circuits that contribute to physiological functions beyond homeostatic control, from the emotional experience and the genesis of feelings (8) to decision making (9, 10). The debate about the role of the ANS in emotions can be condensed into two views: specificity or causation (4). The specificity view is related to the James–Lange theory, which states that bodily responses precede emotions’ central processing, meaning that bodily states would be a response to the environment, followed by an interpretation carried out by the CNS that would result in the feeling felt. However, causation theories represent an updated view of the James–Lange theory, suggesting that peripheral changes influence the conscious emotional experience; from a biological point of view this may reflect the fact that autonomic nervous signals from the body do influence perceptual activity in the brain (11, 12). In this regard, subjective perception may be influenced or shaped by ascending communication from visceral inputs to the brain (13–15).Functional models of CNS and ANS interplay have described bidirectional dynamics in emotions (16–18). In particular, the functional brain–heart interplay (BHI) involves brain structures that comprise the central autonomic network (CAN), which has been described as being in charge of autonomic control (19, 20). Moreover, the default mode network (DMN) has been found to be involved in autonomic control (21) and tasks of self-related cognition and interoception (22, 23), suggesting that the DMN participates in both ascending and descending communications with the heart. Finally, the constructed emotion theory suggests how DMN together with other intrinsic networks is crucial in the genesis of emotion and emotional experience (3).Psychophysiological studies have uncovered several correlates of different autonomic signals in the brain during emotional experiences (24–27). To understand these correlations and the functional interactions between the heart and brain, various signal processing methods have been proposed to investigate functional BHI through noninvasive recordings (28). The study of emotions using these methods comprises the analysis of heartbeat-evoked potentials (29), nonlinear couplings (30), and information transfer modeling (31). However, the causative role of bodily inputs remains unknown (4) and, more specifically, the temporal and causal links between cortical and peripheral neural dynamics in both ascending and descending directions, i.e., from the brain to the body and from the body to the brain, are still to be clarified.In this study, we take a step forward in answering these scientific questions and investigate whether peripheral neural dynamics play a causal role in the genesis of emotions. We applied a mathematical model of functional BHI based on synthetic data generation (SDG) (32), estimating the directionality of the functional interplay using simultaneous electroencephalography (EEG) and electrocardiography (ECG) recordings gathered from healthy subjects undergoing emotion elicitations with video clips, the publicly available DEAP and MAHNOB datasets (33, 34). ECG series were analyzed to derive heart-rate variability (HRV) series, which result from the concurrent activity of the sympathetic and parasympathetic (vagal) branches of the ANS acting to regulate the heartbeat. We hypothesize that, from a neurobiological point of view, feelings and subsequent emotional experiences arise from the mutual interplay between brain and body, particularly in which the CNS integrates the afferent ANS information outflow, namely from-heart-to-brain interplay, which actually triggers a cascade of cortical neural activations that, in turn, modulate directed neural control onto the heart, namely from brain-to-heart interplay.