Humans can adapt their movements in response to expected and unexpected perturbations. The speed and accuracy of these movement corrections may depend on the type of sensory information driving the perception of these perturbations. While previous research has indicated that corrections based on somatosensory information, comprised of proprioceptive and tactile inputs, are faster than corrections based on visual information, other studies have found comparable correction speeds in response to visual and tactile inputs. The purpose of this study was to systematically investigate the latencies (how fast) and magnitudes (how large) of movement corrections in response to perturbations of external visual targets, as well as somatosensory (proprioceptive and tactile) and tactile targets on the non-reaching limb. Participants performed reaching movements to a light-emitting diode (i.e., visual target), the felt position of a brush touching the index finger of the non-reaching hand (i.e., a tactile target), and th...

Attention-deficit/hyperactivity disorder (ADHD) adversely affects the learning, social interaction, and daily living of affected children. Atomoxetine (ATX) hydrochloride (HCI) has been widely used in clinical practice. Electroencephalogram (EEG) biofeedback, as a nonpharmacological treatment approach, has also demonstrated potential in improving symptoms in children with ADHD. We aimed to investigate the clinical efficacy of combining ATX HCI with EEG biofeedback in the treatment of ADHD in children. We hypothesized that this combined therapy would be more effective in alleviating symptoms in children with ADHD. Ninety children with ADHD were randomly separated into the control group (receiving ATX HCI treatment for 12 weeks) and study group (receiving ATX HCI treatment for 12 weeks combined with 60 sessions of EEG biofeedback treatment; n  = 45). Swanson, Nolan, and Pelham-IV (SNAP-IV) rating scale scores, integrated visual and auditory continuous performance test results, Conners parent symptom question...

The importance of animal models to an understanding of the development and plasticity of visual functions was evident from the outset of the long experimental collaboration of David Hubel and Torsten Wiesel in the early 1960s. Their initial work on kittens had massive impact in part because of the recognition that kittens share with primates substantial similarities of visual system organization and plasticity (e.g., eye-specific lamination of the thalamus and columnar organization of the visual cortex), as well as comparable visual abilities (including stereoscopic vision). In addition the plasticity demonstrated in response to early periods of selected visual exposure provided a glimpse into the origins of amblyopia. Five decades ago my laboratory developed a method for the fast measurement of visual thresholds in kittens in order to capture the consequences for spatial vision of the rapid physiological changes that occurred in the visual cortex during both typical development and those that follow vario...

The primary motor cortex (M1) is strongly engaged by movement planning and execution. However, the role of M1 activity in voluntary grasping is still not completely understood. Here we analyze recordings of M1 neurons during the execution of a delayed reach-to-grasp task, where monkeys had to actively grasp an object with either a side or a precision grip, and then pull it with a low or high amount of force. Single cell and neural populations analyses showed that grip type was robustly and specifically encoded by a large population of neurons, while force level was weakly and transiently encoded within mixed-selective neurons that also encoded grip type. Notably, the grip type was stably decoded from motor cortical populations during the preparation and execution epochs of the task. Our results are consistent with the idea that planning and performing specific grasping movements are high-level skills that strongly engage M1 neurons, while the execution of pulling force might be prominently encoded at lower...

Mouse lines with tetracycline-controlled gene expression in specific neuronal populations provide valuable tools for studying their development, function, connectivity, and pathology in vivo. Our initial goal was to generate a mouse model that could express amyotrophic lateral sclerosis-associated genes specifically in spinal cord motor neurons under the control of the HB9 promoter. However, HB9-tTA mice unexpectedly direct target gene expression in a small subset of dorsal horn neurons. These mice represent a new tool for scientists who are interested in studying these spinal cord neurons.

Early and accurate diagnosis of Alzheimer's disease (AD) will be key for effective personalized treatment plans ( [Cummings, 2023][1]). Significant difficulties in auditory processing have been frequently reported in many patients with mild cognitive impairment, the prodromal form of AD ( [Tarawneh et al., 2022][2]), making it an outstanding candidate as AD diagnostic biomarker. However, the efficiency of diagnosis with this parameter has not been explored. Here we show that when male mice with amyloidosis begin to show memory decline, changes in the auditory brainstem response (ABR) to clicks enable the reliable diagnosis of disease using a machine learning algorithm. Interpretation of the machine learning diagnosis revealed that the upper levels of the auditory pathway, including the inferior colliculus, were the probable sources of the defects. Histological analyses show that in these locations, neuroinflammation and plaque deposition temporally correlate with behavioral changes consistent with memory l...

What the basal ganglia do is an oft-asked question; answers range from the selection of actions to the specification of movement to the estimation of time. Here, I argue that how the basal ganglia do what they do is a less-asked but equally important question. I show that the output regions of the basal ganglia create a stringent computational bottleneck, both structurally, because they have far fewer neurons than do their target regions, and dynamically, because of their tonic, inhibitory output. My proposed solution to this bottleneck is that the activity of an output neuron is setting the weight of a basis function, a function defined by that neuron’s synaptic contacts. I illustrate how this may work in practice, allowing basal ganglia output to shift cortical dynamics and control eye movements via the superior colliculus. This solution can account for troubling issues in our understanding of the basal ganglia: why we see output neurons increasing their activity during behavior, rather than only decreas...

Chronic pain affects millions globally, yet no universally effective treatment exists. The primary motor cortex (M1) has been a key target for chronic pain therapies, with electrical stimulation of the M1 (eMCS) showing promise. However, the mechanisms underlying M1-mediated analgesic effects are not fully understood. We investigated the role of the primary somatosensory cortex (S1) in M1-mediated analgesia using a neuropathic pain mouse model. In this model, neuropathic pain is associated with increased spontaneous activity of layer V pyramidal neurons (LV-PNs) in the S1, partly attributed to the reduced activity of somatostatin-expressing inhibitory neurons (SST+ INs), which normally suppress LV-PNs. While manipulation of either LV-PNs or SST+ INs has been shown to alleviate pain, the role of S1 in M1-mediated analgesia has not been identified. Using multichannel silicon probes, we applied eMCS to neuropathic mice and observed significant analgesia. Histological analyses revealed that eMCS activated SST+...

The scientific landscape in the United States is experiencing a significant shift. Recent developments have created new challenges for US researchers, US institutions, and scientific societies worldwide that warrant our collective attention and thoughtful response. These changes present an opportunity to reaffirm the fundamental importance of scientific exchange. Recent policy changes have significantly altered funding for biomedical research in the United States. The National Institutes of Health (NIH) has announced substantial reductions in funding and has canceled study sections. Although the story is still unravelling, the decision to limit the overheads to 15% may threaten the very existence of some laboratories with obvious disastrous human consequences. This also includes the closure of NIH-core funded facilities and the firing of scientific personnel. The current climate has changed the way international researchers consider future travel to the United …

In the article “Nucleus Accumbens Microcircuit Underlying D2-MSN-Driven Increase in Motivation,” by Carina Soares-Cunha, Bárbara Coimbra, Ana Verónica Domingues, Nivaldo Vasconcelos, Nuno Sousa, and Ana João Rodrigues, …