Computational evaluation of load carriage effects on gait balance stability

Evaluating the effects of load carriage on gait balance stability is important in various applications. However, their quantification has not been rigorously addressed in the current literature, partially due to the lack of relevant computational indices. The novel Dynamic Gait Measure (DGM) characterizes gait balance stability by quantifying the relative effects of inertia in terms of zero-moment point, ground projection of center of mass, and time-varying foot support region. In this study, the DGM is formulated in terms of the gait parameters that explicitly reflect the gait strategy of a given walking pattern and is used for computational evaluation of the distinct balance stability of loaded walking. The observed gait adaptations caused by load carriage (decreased single support duration, inertia effects, and step length) result in decreased DGM values (p < 0.0001), which indicate that loaded walking motions are more statically stable compared with the unloaded normal walking. Comparison of the DGM with other common gait stability indices (the maximum Floquet multiplier and the margin of stability) validates the unique characterization capability of the DGM, which is consistently informative of the presence of the added load.     

The relative contributions of sagittal,frontal, and transverse joint works to self-paced incline and decline slope walking

Positive and negative work are generated at the lower limb joints in order to locomote over various terrains. Joint work quantifies the changes in energy that are necessary to adapt gait to environmental demands. The aim of this study was to quantify 3D joint work at the hip, knee, and ankle during slope walking. Work was calculated for ten males (23.9 ± 1.1 years) walking at a self-selected speed on inclines and declines (−20, −12, −6, 0, 6, 12, 20 degrees). Sagittal positive work significantly increased at the hip, knee, and ankle for incline walking (for example, hip positive work increased 153%, 280%, and 453% for 6, 12, and 20 degrees, respectively; knee and ankle positive work also increased) (p ≤ 0.05), in order to raise and propel the body forward. Sagittal negative work increased significantly at the hip, knee and ankle for decline walking (for example, knee negative work increased 193%, 355%, and 496% for −6, −12, and −20 degrees, respectively; hip and ankle negative work also increased) (p ≤ 0.05), in order to control body descent. These substantial changes in work will be especially challenging for people with compromised strength due to age and disease. Furthermore, changes in work were not limited to the sagittal plane: 46% of the total hip joint work occurred in the frontal and transverse planes for six degree decline walking. Thus, decline walking placed greater demands on the hip ab/adductors and rotators, and this may be related to the greater risk of falls observed for descent versus ascent.     

Extended Evolutionary Fast Learn-to-Walk Approach for Four-Legged Robots

Robot locomotion is an active research area. In this paper we focus on the locomotion of quadruped robots. An effective walking gait of quadruped robots is mainly concerned with two key aspects, namely speed and stability. The large search space of potential parameter settings for leg joints means that hand tuning is not feasible in general. As a result walking parameters are typically determined using machine learning techniques. A major shortcoming of using machine learning techniques is the significant wear and tear of robots since many parameter combinations need to be evaluated before an optimal solution is found.This paper proposes a direct walking gait learning approach, which is specifically designed to reduce wear and tear of robot motors, joints and other hardware. In essence we provide an effective learning mechanism that leads to a solution in a faster convergence time than previous algorithms. The results demonstrate that the new learning algorithm obtains a faster convergence to the best solutions in a short run. This approach is significant in obtaining faster walking gaits which will be useful for a wide range of applications where speed and stability are important. Future work will extend our methods so that the faster convergence algorithm can be applied to a two legged humanoid and lead to less wear and tear whilst still developing a fast and stable gait.     

Intracellular recordings from nonspiking interneurons in a semiintact,tethered walking insect

Nonspiking interneurons were investigated in a tethered, walking insect, Carausius morosus, that was able to freely perform walking movements. Experiments were carried out with animals walking on a lightweight, double-wheel treadmill. Although the animal was opened dorsally, the walking system was left intact. Intracellular recordings were obtained from the dorsal posterior neuropil of the mesothoracic ganglion. Nonspiking inter-neurons, in which modulations of the membrane potential were correlated with the walking rhythm, were described physiologically and stained with Lucifer Yellow. Interneurons are demonstrated in which membrane potential oscillations mirror the leg position or show correlation with the motoneuronal activity of the protractor and retractor coxae muscles during walking. Other interneurons showed distinct hyperpolarizations at certain important trigger points in the step cycle, for example, at the extreme posterior position. Through electrical stimulation of single, nonspiking interneurons during walking, the motoneuronal activity in two antagonistic muscles—protractor and retractor coxae—could be reversed and even the movement of the ipsilateral leg could be influenced. The nonspiking interneurons described appear to be important premotor elements involved in walking. They receive, integrate, and process information from different leg proprioceptors and drive groups of leg motoneurons during walking.     

苏云金芽胞杆菌大质粒pBMB28的克隆

苏云金芽胞杆菌幕虫亚种YBT-020具有典型的晶胞粘连表型。在前期的研究中,通过质粒消除实验,推测晶胞粘连现象与YBT-020内生质粒pBMB28有关。为了定位质粒pBMB28上控制晶胞粘连表型的基因,首先对质粒pBMB28进行克隆。利用穿梭载体pEMB0557,成功构建了苏云金芽胞杆菌YBT-020的基因组人工染色体(BAC)文库。前期的研究表明晶体蛋白基因cry28Aa定位在质粒pBMB28上,根据cry28Aa基因序列设计引物,从文库中筛选到含有cry28Aa的重组质粒pBMB231。镜检和SDS-PAGE证明质粒pBMB231转化无晶体突变株BMB171形成的重组子BMB231可以产生Cry28Aa晶体蛋白,但不能恢复晶胞粘连表型。对重组质粒pBMB231的插入片段末端序列测定并设计引物筛选文库,通过染色体步移方式得到4个可以重叠覆盖质粒pBMB28不同区域的克隆子,从而克隆了该质粒。对这4个克隆子末端测序和酶切分析,测算出该质粒的大小约为140 kb。进一步确定应用基因组BAC文库以及重叠片段筛选的方法,可以快速有效的克隆苏云金芽胞杆菌大质粒。     

早期强化步行基本功训练对脑卒中的预后分析

目的：分析早期强化步行基本功训练对脑卒中预后的影响。方法：选取我院2008年10月一2011年10月收治的176例恢复期脑卒中患者,按照随机数字表分为观察组及对照组,各88例,均接受常规药物治疗和康复训练,观察组在此基础上接受早期强化步行基本功训练,对比两组患者的预后。结果：两组患者治疗后FMA—LE、BBS及MBI评分均见上升,观察组较对照组上升程度更为明显（P〈0．05）,T2时期观察组评分亦见升高,而对照组评分与T1时期相比无明显统计学差异（P〉0．05）;两组患者治疗后步长、步宽及步速均见上升,观察组较对照组上升程度更为明显（P〈0．05）,T2时期观察组步态参数亦见升高,而对照组步态参数与T1时期相比无明显统计学差异（P〉0．05）。结论：早期强化步行基本功训练能够有效改善脑卒中患者下肢运动功能和平衡能力,保证治疗后步行功能,避免生活质量下降,该康复方法值得广泛推广。     

Descending interneurones from the brain and suboesophageal ganglia and their role in the control of locust behaviour

Lesion and stimulation experiments suggest that the suboesophageal ganglion (SOG) plays a special role in the control of insect behaviour: in bilateral coordination and by maintaining ongoing motor activity. Anatomical observations indicate that there are descending interneurones (DINs) originating in the SOG in addition to those from the brain. An SOG preparation for sampling both types of DIN intracellularly in walking locusts is described. Forty-three units showing activity changes during leg movements and walking were recorded. Using dye injection six were shown to be through-running axons; one was an SOG ascending interneurone; and eight were SOG DINs, 7 contralateral, one ipsilateral. All fired before or during movements and received various sensory inputs. Many gave complex responses to different modalities, several showing directional preferences. Some SOG neurones showed spontaneous changes in activity; activity outlasting movements; or responses to passive as well as active movements. These preliminary results suggest neuronal substrates for the special functions of the SOG in behaviour. They also indicate that DINs, rather than being simple relays, are part of a dynamic network which includes the motor centres. Regulation of complex and subtle aspects of behaviour may be achieved by dynamic and sequential patterns of activity in groups of DINs, some of which may be multifunctional.     

Influence of habitat structure on the phonotactic strategy of a parasitoid fly Emblemasoma auditrix

Abstract.  1. Females of the parasitoid fly Emblemasoma auditrix find their host cicadas ( Okanagana rimosa ) using the acoustic signals produced by the host. The phonotactic behaviour of the parasitoid was studied with regard to differently structured habitats.
2. Habitats were modified experimentally within a distance of 2.5 m (approximately the natural range of phonotaxis) from a loudspeaker broadcasting a model of the host calling song.
3. Video analysis showed that in an open habitat (no landmarks) more than 60% of the flies performed a direct flight towards the loudspeaker.
4. In structured habitats (with one to three landmarks) more than 90% of the flies landed on their way to the acoustic target.
5. In about 50% of the landings flies paused for several seconds indicating re-orientation during that time. Several flies included sequences of walking in their approach behaviour, whereby most walking occurred close to the loudspeaker.
6. In summary, the phonotactic approach and host finding depends on the habitat structure.     

A neurobiological model of the recovery strategies from perturbed walking

This paper proposes a human mimetic neuro-musculo-skeletal model to simulate the recovery reactions from perturbations during walking. The computational model incorporates nonlinear viscoelastic muscular mechanics, supraspinal control of the center-of-mass, spinal pattern generator including muscle synergy network, spinal reflexes, and long-loop reflexes. Especially the long-loop reflexes specify recovery strategies based on the experimental observations [Schillings, A.M., van Wezel, B.M.H., Mulder, T.H., Duysen, J., 2000. Muscular responses and movement strategies during stumbling over obstacles. J. Neurophysiol. 83, 2093–2102; Eng, J.J., Winter, D.A., Patla, A.E., 1994. Strategies for recovery from a trip in early and late swing during human walking. Exp. Brain Res. 102, 339–349]. The model demonstrates two typical recovery strategies, i.e., elevating and lowering strategies against pulling over a swing leg. Sensed perturbation triggers a simple tonic pulse from the cortex. Depending on the swing phase, the tonic pulse activates a different compound of muscles over lower limbs. The compound induces corresponding recovery strategies. The reproduction of principal recovery behaviors may support the model's proposed functional and/or anatomical correspondence.