Electrical Stimulation Intensity to Induce Sensory Reweighting Dynamics While Standing on Balance Board.

In human postural control, maladaptation of sensory reweighting to sudden environmental changes is one of the main causes of postural instability. Providing sensory cues for body motion by means of stimulation could induce the sensory reweighting dynamics. In this paper, we aimed to investigate the intensity level of electrical stimulation to induce sensory reweighting dynamics while standing on a balance board under three conditions: no stimulation (control), electrotactile stimulation (ETS) at a low-intensity level, and electrical muscle stimulation (EMS) at a high-intensity level.

Induced effects of electrical muscle stimulation and visual stimulation on visual sensory reweighting dynamics during standing on a balance board.

Providing instruction cues on body motions using stimulations has the potential to induce sensory reweighting dynamics. However, there are currently very few quantitative investigations on the difference in the induced effects on the sensory reweighting dynamics between stimulation methods. We therefore investigated the difference in the induced effects of electrical muscle stimulation (EMS) and visual sensory augmentation (visual SA) on sensory reweighting dynamics during standing on a balance board.

Force Control on Fingertip Using EMS to Maintain Light Touch.

Light touch on a rigid surface with minimal force below a specific threshold reduces postural sway by providing additional sensory cues from the fingertips. The feasibility of maintaining light touch depends on subject characteristics and task difficulty. Therefore, we introduce a method of maintaining light touch by using electrical muscle stimulation (EMS).

Shoot has important roles in strigolactone production of rice roots under sulfur deficiency.

Strigolactones (SLs) are a class of plant hormones that control plant architecture. SL levels in roots are determined by the nutrient conditions in the rhizosphere, especially the levels of nitrogen (N) and phosphorus (P). Our previous research showed that SL production is induced in response to deficiency of sulfur (S) as well as of N and P, and inhibits shoot branching, accelerates leaf senescence, and regulates lamina joint angle in rice.

Strigolactones Decrease Leaf Angle in Response to Nutrient Deficiencies in Rice.

Strigolactones (SLs) are a class of plant hormones that are synthesized from -carotene through sequential reactions catalyzed by DWARF (D) 27, D17, D10, and OsMORE AXILLARY GROWTH (MAX) 1 in rice ( L.). In rice, endogenous SL levels increase in response to deficiency of nitrogen, phosphate, or sulfate (-N, -P, or -S).

Low Infection of in Micro-Tom Mutants Deficient in .

Strigolactones (SLs), a group of plant hormones, induce germination of root-parasitic plants and inhibit shoot branching in many plants. Shoot branching is an important trait that affects the number and quality of flowers and fruits. Root-parasitic plants, such as spp.

Upregulation of is associated with increased strigolactone levels under sulfur deficiency in rice.

Plants produce strigolactones (SLs) in roots in response to nitrogen or phosphate deficiency. To evaluate SL levels under other mineral deficiencies in rice, we cultivated rice seedlings in hydroponic media without nitrogen, phosphorus, potassium, sulfur, calcium, magnesium, and iron. Tiller bud outgrowth was stimulated under calcium deficiency because of low SL levels.