deuteranopia
简明释义
英[ˌdjuːtərəˈnəʊpɪə]美[ˌdjʊtərəˈnopɪə]
n. [眼科] 绿色盲;[耳鼻喉] 第二型色盲
英英释义
A type of color blindness characterized by the inability to perceive green light due to a deficiency in green cone photoreceptors in the retina. | 一种色盲,特征是由于视网膜中绿色锥体光感受器的缺乏而无法感知绿色光。 |
单词用法
患有deuteranopia的个体 | |
deuteranopia的诊断 | |
deuteranopia测试 | |
deuteranopia症状 |
同义词
| 绿色盲 | People with deuteranopia often confuse red and green colors. | 患有绿色盲的人常常会混淆红色和绿色。 | |
| 偏绿盲 | Deuteranopia is one of the most common types of color blindness. | 绿色盲是最常见的色盲类型之一。 |
反义词
| 正常视力 | People with normal vision can distinguish between a wide range of colors. | 具有正常视力的人能够区分广泛的颜色。 | |
| 三色视觉 | Trichromacy allows individuals to perceive colors accurately. | 三色视觉使个体能够准确感知颜色。 |
例句
1.Conclusion (1) it is feasible to use chromatic VEP for examining congenital color vision deficient, especially for red green blindness and deuteranopia.
结论(1)颜色视觉诱发电位客观地检查先天性色觉异常是可行的,对红绿色盲和绿色盲尤为敏感。
2.Conclusion (1) it is feasible to use chromatic VEP for examining congenital color vision deficient, especially for red green blindness and deuteranopia.
结论(1)颜色视觉诱发电位客观地检查先天性色觉异常是可行的,对红绿色盲和绿色盲尤为敏感。
3.It explained the basic reason of protanopia and deuteranopia occurrence with the equilibrium theories.
并以第一色盲、第二色盲为例,阐述色盲现象产生的根本原因。
4.It explained the basic reason for protanopia and deuteranopia occurrence with the equilibrium theories.
它用平衡理论解释了发生红色盲和绿色盲的根本原因。
5.When designing websites, it's important to consider users with deuteranopia to ensure accessibility.
在设计网站时,考虑到有色盲(绿盲)的用户以确保可访问性是很重要的。
6.In sports, players with deuteranopia might have difficulty identifying team colors.
在运动中,患有色盲(绿盲)的运动员可能难以识别球队颜色。
7.A common challenge for those with deuteranopia is distinguishing traffic lights.
对于患有色盲(绿盲)的人来说,区分交通信号灯是一个常见的挑战。
8.People with deuteranopia often confuse green and red colors.
患有色盲(绿盲)的人常常混淆绿色和红色。
9.Artists may need to adapt their palettes for viewers with deuteranopia.
艺术家可能需要调整他们的调色板,以适应有色盲(绿盲)的观众。
作文
Color vision is a fascinating aspect of human perception, allowing us to experience the world in vibrant hues. However, for some individuals, this experience is not as rich due to color vision deficiencies. One such condition is known as deuteranopia, which is a type of red-green color blindness. People with deuteranopia have difficulty distinguishing between certain colors, particularly greens and reds, because their eyes lack the medium-wavelength cones that are essential for detecting green light. This condition affects approximately 1% of the male population and is much less common in females, highlighting its genetic basis linked to the X chromosome.Understanding deuteranopia requires a look into the biology of our eyes. The retina contains photoreceptor cells called cones, which are responsible for color vision. There are three types of cones: those sensitive to short wavelengths (blue), medium wavelengths (green), and long wavelengths (red). In individuals with deuteranopia, the medium-wavelength cones are absent or non-functional, leading to a diminished ability to perceive green colors. As a result, they may confuse shades of red and green, often perceiving them as similar or indistinguishable.The implications of deuteranopia extend beyond simply seeing colors differently; they can impact daily life significantly. For instance, tasks that require color discrimination, such as reading traffic lights, interpreting graphs, or selecting ripe fruits, can become challenging. This can lead to misunderstandings or safety concerns. Moreover, individuals with deuteranopia may find it difficult to engage in activities that rely heavily on color differentiation, such as art or design, where color harmony plays a crucial role.Despite these challenges, many individuals with deuteranopia adapt remarkably well. They develop compensatory strategies to navigate their environments. For example, they may learn to rely more on brightness and context rather than color alone. Technology has also made strides in assisting those with color vision deficiencies. Color-correcting glasses are now available, which can enhance color perception for some users, making their experiences more similar to those without color blindness.Awareness and understanding of deuteranopia are important for fostering inclusivity. Educators and employers can create environments that accommodate individuals with color vision deficiencies by using patterns or labels instead of solely relying on color coding. Additionally, raising awareness about deuteranopia can help reduce stigma and promote empathy towards those who experience the world differently.In conclusion, deuteranopia is more than just a medical term; it represents a unique way of experiencing color. While it presents certain challenges, individuals with this condition often find innovative ways to thrive. By promoting understanding and inclusivity, society can ensure that everyone, regardless of their color vision, can enjoy the beauty of the world around them.
色彩视觉是人类感知的一个迷人方面,使我们能够以生动的色调体验世界。然而,对于一些人来说,由于色彩视觉缺陷,这种体验并不那么丰富。其中一种情况被称为deuteranopia,这是一种红绿色盲。患有deuteranopia的人在区分某些颜色时遇到困难,尤其是绿色和红色,因为他们的眼睛缺乏检测绿色光线所必需的中波长锥体。这种情况影响大约1%的男性人口,而在女性中则少见得多,突显了其与X染色体相关的遗传基础。理解deuteranopia需要了解我们眼睛的生物学。视网膜中含有称为锥体的光感受器细胞,它们负责色彩视觉。锥体有三种类型:对短波长(蓝色)、中波长(绿色)和长波长(红色)敏感。在患有deuteranopia的个体中,中波长锥体缺失或功能失常,导致感知绿色的能力减弱。因此,他们可能会混淆红色和绿色的阴影,通常将它们视为相似或无法区分。deuteranopia的影响不仅仅是看到颜色的不同;它们可以显著影响日常生活。例如,需要颜色区分的任务,如阅读交通信号灯、解读图表或选择成熟的水果,可能变得具有挑战性。这可能导致误解或安全隐患。此外,患有deuteranopia的人可能发现参与高度依赖颜色区分的活动(如艺术或设计)变得困难,在这些活动中,色彩和谐起着至关重要的作用。尽管面临这些挑战,许多患有deuteranopia的人适应能力极强。他们发展出补偿策略来驾驭他们的环境。例如,他们可能学会更多地依赖亮度和上下文,而不是单纯依赖颜色。科技也在帮助那些色彩视觉缺陷者方面取得了进展。现在有可用的色彩校正眼镜,可以增强某些用户的色彩感知,使他们的体验更接近没有色盲的人。提高对deuteranopia的认识和理解对于促进包容性至关重要。教育工作者和雇主可以通过使用图案或标签而不是仅仅依靠颜色编码来创造适合色彩视觉缺陷者的环境。此外,提高对deuteranopia的认识可以帮助减少污名化,并促进对那些以不同方式体验世界的人的同情。总之,deuteranopia不仅仅是一个医学术语;它代表了一种独特的色彩体验方式。虽然它带来了某些挑战,但患有这种疾病的人往往找到创新的方法来茁壮成长。通过促进理解和包容,社会可以确保每个人,无论其色彩视觉如何,都能享受周围世界的美丽。
