但是艾德所发现的,是地球上大多数的生物组织是不靠视觉和听觉来交流的。
But what Ed was discovering is that most organisms on Earth do not communicate by sight and sound.
但是我们知道,自然界已经为它的生物们建立了一些非常精细的听觉机制。
We do know, however, that nature has set up some very delicate hearing mechanisms for its creatures.
听力丧失以及相关失衡的主要原因在于人类和其他一些哺乳动物的听觉细胞无法自行再生。这点和其他生物如鸟类不同。
The major reason for hearing loss and certain balance disorders is that - unlike other species such as birds - humans and other mammals are unable to spontaneously regenerate these hearing cells.
此课为听觉系统的分子生物学之导论课程。
An introductory course in the molecular biology of the auditory system.
在目前生物及医学技术的限制下,超声骨传导人工听觉装置是恢复全聋人听觉的一种比较有效的方法。
At present, the biology and the medicine technology are limit. Artificial Ultrasonic Bone-Conducted hearing System can help the deaf person restore the sense of hearing.
本文结合分析《听觉生物物理基础》网络课件制作过程,提出了对这些问题的解决办法。
This paper analyses these problems in the web courseware of "Basis of Auditory Biophysics".
听觉让动物察觉危险、找到食物、寻找伴侣,更复杂的生物还用来沟通。
Hearing enables an animal to sense danger, locate food, find mates, and, in more complex creatures, engage in communication.
应用扫描电镜,结合听觉电生理学和酶组织化学方法研究了缺铁对大鼠听毛细胞结构与功能的影响。结果发现,缺铁组大鼠耳蜗生物电位的产生受到抑制;
The effects of iron deficiency (ID) on the hair cells were studied in growing rats by scanning electron microscopic, auditory elec'crophysiological and histochemical techniques.
听觉神经科学家和生物医学工程师所面临的挑战便是如何去理解大脑中这些转换的编码机制。
The challenges facing auditory neuroscientists and biomedical engineers are to understand neural coding mechanisms in the brain underlying such transformations.
听觉神经科学家和生物医学工程师所面临的挑战便是如何去理解大脑中这些转换的编码机制。
The challenges facing auditory neuroscientists and biomedical engineers are to understand neural coding mechanisms in the brain underlying such transformations.
应用推荐