Genetic analysis of morningness and eveningness

We studied the influence of genetic factors on individual differences in morningness-eveningness in a sample of Dutch twin families. Data were collected from adolescent twins (mean age 17.8 yr) and their parents (mean age of fathers 48.0 yr and of mothers 46.0 yr) and a sample of older twins (mean age 46.5 yr). Scores on morningness-eveningness were rated on a 5-point scale. Parents were more morning oriented than their children, and women were more morning oriented than men. With a twin-family study, separation of genetic and environmental influences on variation in morningness-eveningness is possible. Including parents and older twins in the study makes it possible to explore generation differences in these effects. The correlation between monozygotic twins was more than twice the correlation between dizygotic twins. This indicates that genetic effects may not operate in an additive manner. Therefore, a model that included genetic dominance was explored. Biometrical model fitting showed no sex differences for the magnitude of genetic and environmental factors. The total heritability--the sum of additive and nonadditive genetic influences--for morningness-eveningness was 44% for the younger generation and 47% for the older generation. However, the genetic correlation between the generations turned out to be lower than 0.5, suggesting that different genes for morningness-eveningness are expressed in both generations

'VOR' - an interactive iPad model of the combined angular and linear vestibulo-ocular reflex

The mammalian vestibular system consists of a series of sensory organs located in the labyrinths of the inner ear that are sensitive to angular and linear movements of the head. Afferent inputs from the vestibular end organs contribute to balance, proprioception and vision. The vestibulo-ocular reflex (VOR) driven by these sensory inputs produces oculomotor responses in a direction opposite to head movement which tend to stabilise visual images on the retina. We present a model, in the form of a software application called VOR, which represents a simplified view of this complex system. The basis for our model is the hypothesis that afferent vestibular signals are integrated to maintain a notional internal representation of the head position (RHP). The vestibulo-ocular reflex maintains gaze towards a world-fixed point relative to the RHP, regardless of the actual head position. The RHP will imperfectly match the real head position when end organ input imperfectly reports head movements, such as can occur in cases of organ dysfunction and even in healthy subjects due to adaptation to motion stimuli. We do not claim that any specific observable part of the real vestibulo-ocular system corresponds to the RHP, but it seems reasonable to suggest that it might exist as a literal "neural network", trained through evolution and experience to maintain gaze during head movement. We hypothesise that the real VOR is supported by this internal representation, continually updated by afferent signals from the vestibular end organs, and that VOR eye responses tend to direct the eyes towards a fixed point in the world. Human vestibulo-ocular research typically employs equipment to which a subject is securely attached and allows rotation around, and sometimes linear movement along, one or more axes ("rotating chair") while attempting to maintain gaze on a fixation point, fixed relative to the head or world. A series of consecutive movements are referred to as a "motion profile". Meanwhile eye movements are recorded, using scleral search coils (or, more recently, video cameras and image-processing software) which can detect the horizontal, vertical and torsional components of the direction of each eye. VOR allows the user to define motion profiles and predicts the eye movements that a researcher or clinician might expect to observe in a real subject during such motion profiles. For example, the "on-centre rotation" motion profile specifies that the subject's head is positioned upright and centred around the vertical axis of the rotating chair, with a chair-fixed fixation point 1m in front of the subject. The chair accelerates angularly to 200°/sec over 20 seconds, rotates at a constant 200°/sec for 60 seconds, then decelerates to stationary over 20 seconds. The model accurately predicts the transient nystagmus that would be expected: its direction, duration, phase velocity and even the brief secondary nystagmus which is characteristic of adaptation to constant velocity rotation. VOR also allows the user to define end organ condition configurations, e.g. "normal", "bilateral vestibular loss", "unilateral superior neuritis", which are represented as a series of response gains attached to the sensory inputs from each end organ, relative to a nominal perfect gain of 1, and various other parameters which are derived from the human vestibular system, including the rate of drift of gaze to fixation point in light and dark, the rate at which the end organs adapt to constant stimuli, and quick-phase trigger dependencies. The VOR is not the only source of eye movement while attempting to maintain gaze on a fixation point. In our model, eye position drifts towards the fixation point at a nominal fixed rate. If this slow drift is insufficient to maintain gaze on the fixation point, a saccade or quick phase is triggered. Hence the transduction of mechanical forces at the labyrinths into sensory signals, subject to end organ conditions and adaptation that reduce the strength of the neuronal signals, maintain the RHP. Eye movement is then determined entirely by (a) the direction from RHP to the (world-referenced) fixation point, and (b) the disparity between eye direction and actual fixation point (which may be head-referenced). To validate the model, we prepared 24 motion profile/end organ condition combinations, compared the outputs from our model with real world observations, and found the results to be similar. Similarities include a simple first approximation of the linear and angular VOR; nystagmus caused by a subject's attempts to maintain fixation on a head-referenced target during head movement; decay of nystagmus through adaptation to stimulus, including secondary nystagmus; indefinitely prolonged nystagmus during off-vertical axis rotation (OVAR); rapid decay of nystagmus during the "tilt dump" motion profile, and dynamic cyclovergence during vertical linear acceleration. VOR is programmed in Objective-C using Xcode and runs on the Apple iPad. Its screen displays a 3d graphical representation of the virtual subject's head and eyes, including imaginary lines of sight to clarify eye movements. The user may program an effectively unlimited series of linear and angular motions of the rotating chair, and of the virtual subject's head relative to the chair. They may also program the gain (roughly, the sensitivity) associated with each end organ and other variables relating to the subject. They may select a series of internal variables to chart during the motion profile such as head velocity, eye direction, neuron firing rates, etc., while simultaneously displaying the head and eyes. VOR can record a video screen capture of the virtual head, eyes and lines of sight during the execution of a motion profile, a CSV file containing the internal variables at each time interval, a PNG image of the labelled chart, PDF descriptions of the motion profile and end organ condition configurations, and data files defining the motion profiles and end organ conditions which can then be exchanged between researchers/clinicians. Predefined motion profiles include: lateral, LARP and RALP head impulses; lateral head impulse with close fixation point; sinusoidal yaw, on-centre rotation, linear heave along Y axis, linear oscillation along X, Y and Z axes; linear sled along Y axis; forward- and backward-facing centrifugation; off-vertical axis rotation; tilt dump; and head tilt. Predefined conditions include: normal; left unilateral vestibular loss; bilateral vestibular loss; left superior neuritis; and "perfect" (unrealistic gain of 1 in otoliths, producing perfect linear VOR). All of these motion profiles and conditions may easily be modified, created and shared

Brain-derived neurotrophic factor, neurofilament light and glial fibrillary acidic protein do not change in response to aerobic training in people with MS-related fatigue – a secondary analysis of a randomized controlled trial

Health and self-regulatio

HST/STIS Observations of the Optical Counterpart to GRB 970228

We report on observations of the fading optical counterpart of the gamma-ray burst GRB 970228, made on 4~September~1997 using the STIS CCD on the Hubble Space Telescope. The unresolved counterpart is detected at V=28 +/- 0.25, consistent with a continued power-law decline with exponent -1.14 +/- 0.05. No proper motion is detected, in contradiction of some earlier claims. The counterpart is located within, but near the edge of, a faint extended source with diameter ~0."8 and integrated magnitude 25.7 +/- 0.25. Comparison with WFPC2 data taken one month after the initial burst and NTT data taken on March 13 shows no evidence for fading of the extended emission. After adjusting for the probable Galactic extinction in the direction of GRB 970228 of A_v=0.7, we find that the observed nebula is consistent with the sizes of galaxies of comparable magnitude found in the Hubble Deep Field and other deep HST images, and that only 2% of the sky is covered by galaxies of similar or greater surface brightness. Therefore, the extended source observed about GRB 970228 is most likely a galaxy at moderate redshift, and is almost certainly the host of the gamma-ray burst

A Dissipative-Particle-Dynamics Model for Simulating Dynamics of Charged Colloid

A mesoscopic colloid model is developed in which a spherical colloid is represented by many interacting sites on its surface. The hydrodynamic interactions with thermal fluctuations are taken accounts in full using Dissipative Particle Dynamics, and the electrostatic interactions are simulated using Particle-Particle-Particle Mesh method. This new model is applied to investigate the electrophoretic mobility of a charged colloid under an external electric field, and the influence of salt concentration and colloid charge are systematically studied. The simulation results show good agreement with predictions from the electrokinetic theory.Comment: 17 pages, 8 figures, submitted to the proceedings of High Performance Computing in Science & Engineering '1

Indinavir/Low-dose Ritonavir Containing HAART in HIV-1 Infected Children has Potent Antiretroviral Activity, but is Associated with Side Effects and Frequent Discontinuation of Treatment

We here present the study results of 21 HIV-1 infected children who were treated with indinavir plus low-dose ritonavir and two nucleoside reverse transcriptase inhibitors (NRTIs) for 48 weeks. Although this q12h HAART regimen had potent antiretroviral activity, it was frequently associated with side effects and discontinuation of therapy