neurosensory

简明释义

[ˌnʊroʊˈsɛn.sɔːr.i][ˌnʊroʊˈsɛn.sɔːr.i]

adj. 感觉神经的

英英释义

Relating to the sensory functions of the nervous system, including the perception and processing of sensory information.

与神经系统的感官功能相关,包括对感官信息的感知和处理。

单词用法

同义词

neurophysiological

神经生理的

neurophysiological testing is crucial for diagnosing brain disorders.

神经生理测试对于诊断脑部疾病至关重要。

neurological

神经的

neurological assessments help in understanding the nervous system's function.

神经学评估有助于理解神经系统的功能。

sensory

感觉的

sensory receptors play a vital role in how we perceive the world.

感觉受体在我们感知世界的过程中起着至关重要的作用。

反义词

non-neurosensory

非神经感知的

Non-neurosensory pathways are often involved in basic reflex actions.

非神经感知通路通常参与基本的反射动作。

physical

物理的

Physical stimuli can trigger responses independent of neurosensory processing.

物理刺激可以在不依赖神经感知处理的情况下引发反应。

例句

1.Mechanical tensile force arrives at retinal pigment epithelium via retinal neurosensory layer and has an effect on the functions of pigment epithelial cells.

色素上皮受到通过神经上皮层传导过来的机械拉力,对色素上皮细胞的某些功能产生了影响。

2.Objective To evaluate the neurosensory functions of the inferior alveolar nerve(IAN)after two rigid internal fixations for the sagittal split of ramus osteotomy(SSRO)in monkeys.

目的研究下颌支矢状劈开术(SSRO)常用两种内固定方式对下齿槽神经(IAN)功能的影响。

3.Objective to measure the thickness of the neurosensory retina of macula by optical coherence tomography (OCT) in normal eyes to get criterion for clinical practice.

目的应用光学相干断层成像(oct)技术对正常眼黄斑区视网膜神经上皮层厚度进行测定。

4.The neurosensory algorithms in Sleep Genius help your brain get ready for sleep, guide your brain through each stage in the sleep cycle, and wake you with a gentle, refreshing alarm.

在睡眠天才的感觉神经算法帮助你的大脑准备睡觉,通过在睡眠周期的每个阶段引导你的大脑,并唤醒你一个温柔,清爽报警。

5.Objective to investigate the changes of the neurosensory retinal thickness in the macula in high myopia eyes by optical coherence tomography (OCT).

目的应用光学相干断层成像(oct)技术探讨高度近视眼黄斑视网膜神经上皮层厚度的变化。

6.Methods Using OCT, we examined 12 patients with CEC. The size of CNV and the thickness of retinal neurosensory layer in foveola were measured.

方法应用oct技术对12例CEC患者进行检测,测量cnv大小及黄斑中心凹视网膜神经上皮层厚度。

7.Esthesioneuroblastoma (also known as olfactory neuroblastoma) is an uncommon malignant neoplasm of the nasal vault believed to arise from neurosensory receptor cells in the olfactory epithelium.

鼻腔神经胶质瘤(又被称为嗅母细胞瘤)是一种不常见的恶性肿瘤,被认为起源于嗅上皮的感觉神经感受体细胞。

8.Esthesioneuroblastoma (also known as olfactory neuroblastoma) is an uncommon malignant neoplasm of the nasal vault believed to arise from neurosensory receptor cells in the olfactory epithelium.

鼻腔神经胶质瘤(又被称为嗅母细胞瘤)是一种不常见的恶性肿瘤,被认为起源于嗅上皮的感觉神经感受体细胞。

9.ConclusionGenerally, moderate or severe neurosensory hearing loss of both ears occurs at the initial episode of LVAS and aggravates gradually to total deafness.

结论大前庭导水管综合征病儿初次发病时一般为双侧中重度以上感音神经性听力损失,随后波动性听力逐渐下降直至全聋。

10.In children with autism, neurosensory 神经感官的 processing can be significantly different from neurotypical peers.

自闭症儿童的神经感官的处理与神经典型同龄人可能有显著不同。

11.Researchers are exploring how neurosensory 神经感官的 feedback affects motor skills development.

研究人员正在探索神经感官的反馈如何影响运动技能的发展。

12.The neurosensory 神经感官的 systems play a crucial role in our ability to interact with the environment.

神经感官的系统在我们与环境互动的能力中起着至关重要的作用。

13.Therapies that enhance neurosensory 神经感官的 integration can improve sensory processing in individuals with sensory disorders.

增强神经感官的整合的治疗可以改善感官障碍患者的感官处理能力。

14.The study focused on the role of neurosensory 神经感官的 pathways in pain perception.

这项研究集中于神经感官的通路在疼痛感知中的作用。

作文

The human body is a complex system, intricately designed to respond to various stimuli from the environment. One of the most fascinating aspects of this system is how our brain processes sensory information. This processing is often referred to as neurosensory (神经感觉的) function, which plays a crucial role in our perception of the world around us. The term neurosensory encompasses the neural pathways and mechanisms that enable us to interpret sensory input, such as sight, sound, touch, taste, and smell.Understanding neurosensory processes can shed light on how we interact with our surroundings. For instance, when we touch a hot surface, specialized nerve endings in our skin send signals through the spinal cord to the brain, where the sensation of heat is processed. This rapid communication allows us to react quickly, often pulling our hand away before we even consciously realize the danger. Such reflex actions highlight the efficiency of our neurosensory systems.Moreover, neurosensory functions are not limited to basic reflexes. They also play a significant role in our emotional responses and decision-making processes. For example, the smell of freshly baked cookies might evoke feelings of nostalgia or comfort, thanks to the neurosensory connections between our olfactory system and the areas of the brain associated with memory and emotion. This interplay illustrates how deeply intertwined our senses are with our emotional states, influencing our behavior and choices.In recent years, advancements in neuroscience have furthered our understanding of neurosensory systems. Researchers are exploring how these systems can be affected by various factors, including age, health conditions, and environmental influences. For instance, individuals with sensory processing disorders may experience heightened or diminished responses to sensory stimuli, leading to challenges in daily life. By studying the neurosensory mechanisms at play, scientists hope to develop more effective interventions and therapies for those affected.Additionally, technology has begun to play a transformative role in enhancing neurosensory experiences. Virtual reality (VR) and augmented reality (AR) technologies are being utilized to create immersive environments that stimulate multiple senses simultaneously. These innovations can be particularly beneficial in therapeutic settings, helping patients to confront and manage their fears or anxieties in a controlled environment. The integration of neurosensory principles into these technologies opens up new avenues for treatment and rehabilitation.In conclusion, the concept of neurosensory (神经感觉的) function is essential for understanding how we perceive and interact with the world. From basic reflexes to complex emotional responses, our neurosensory systems shape our experiences and influence our behaviors. As research continues to evolve, we gain deeper insights into these intricate processes, paving the way for advancements in both science and technology that can enhance our quality of life. The exploration of neurosensory functions not only enriches our understanding of the human experience but also highlights the importance of maintaining healthy sensory systems for overall well-being.

人类身体是一个复杂的系统,精心设计以响应来自环境的各种刺激。这个系统中最令人着迷的方面之一是我们的脑如何处理感官信息。这种处理通常被称为neurosensory(神经感觉的)功能,在我们对周围世界的感知中发挥着至关重要的作用。术语neurosensory包含了使我们能够解释感官输入的神经通路和机制,例如视觉、听觉、触觉、味觉和嗅觉。理解neurosensory过程可以揭示我们如何与周围环境互动。例如,当我们触摸一个热表面时,皮肤中的专门神经末梢通过脊髓向大脑发送信号,在那里热的感觉被处理。这种快速的沟通使我们能够迅速反应,通常在我们甚至没有意识到危险之前就将手拉开。这种反射动作突显了我们的neurosensory系统的高效性。此外,neurosensory功能不仅限于基本的反射。它们在我们的情感反应和决策过程中也发挥着重要作用。例如,新鲜出炉的饼干的气味可能会唤起怀旧或舒适的感觉,这要归功于我们的嗅觉系统与大脑中与记忆和情感相关的区域之间的neurosensory连接。这种相互作用说明了我们的感官与情感状态之间是多么紧密交织,影响着我们的行为和选择。近年来,神经科学的进展进一步加深了我们对neurosensory系统的理解。研究人员正在探索这些系统如何受到多种因素的影响,包括年龄、健康状况和环境影响。例如,具有感官处理障碍的个体可能会对感官刺激产生过度或减弱的反应,从而在日常生活中面临挑战。通过研究正在发挥作用的neurosensory机制,科学家们希望开发出更有效的干预措施和治疗方案。此外,技术开始在增强neurosensory体验方面发挥变革性的作用。虚拟现实(VR)和增强现实(AR)技术正被用于创造沉浸式环境,同时刺激多个感官。这些创新在治疗环境中特别有益,帮助患者在受控环境中面对和管理他们的恐惧或焦虑。将neurosensory原理整合到这些技术中,开辟了治疗和康复的新途径。总之,neurosensory(神经感觉的)功能的概念对于理解我们如何感知和与世界互动至关重要。从基本的反射到复杂的情感反应,我们的neurosensory系统塑造了我们的体验并影响我们的行为。随着研究的不断发展,我们对这些复杂过程的理解逐渐加深,为科学和技术的进步铺平了道路,从而提高我们的生活质量。对neurosensory功能的探索不仅丰富了我们对人类经验的理解,还突显了保持健康感官系统对整体健康的重要性。