tibiofibula
简明释义
英[ˌtɪbɪəʊˈfɪbjʊlə]美[tɪbioʊˈfɪbjʊlə]
n. [脊椎] 胫腓骨
英英释义
The tibiofibula is a bone that is formed by the fusion of the tibia and fibula, typically found in certain vertebrates such as amphibians and reptiles. | 胫腓骨是由胫骨和腓骨融合形成的一种骨骼,通常出现在某些脊椎动物中,如两栖动物和爬行动物。 |
单词用法
胫腓骨骨折 | |
胫腓骨关节 | |
胫腓骨的结构 | |
胫腓骨在运动中的作用 |
同义词
| 胫腓骨的 | 胫腓关节对于下肢稳定性至关重要。 | ||
| 胫腓关节 | Injuries to the tibiofibular region can affect overall mobility. | 胫腓骨区域的损伤可能会影响整体的移动能力。 |
反义词
| 股骨 | 股骨是人体中最长的骨头。 | ||
| 肱骨 | 肱骨连接肩部与肘部。 |
例句
1.Objective In order to discuss the tibiofibula fracture using lock inner nail and steel plate to fix the curative effect.
目的探讨胫腓骨中下段骨折用交锁髓内钉和腓骨钢板或斯氏针复合固定治疗的疗效。
2.Objective To summarize the clinical features and treatment experience of fracture deformity recovery nonunion of femoral shaft and tibiofibula.
目的总结股骨干及胫腓骨骨折畸形愈合骨不连接临床特征及治疗经验。
3.Objective To explore a repair method of tibiofibula fractures with a calf tissue defect.
目的探讨一种胫腓骨骨折伴小腿软组织缺损的修复方法。
4.Objective To summarize the clinical features and treatment experience of fracture deformity recovery nonunion of femoral shaft and tibiofibula.
目的总结股骨干及胫腓骨骨折畸形愈合骨不连接临床特征及治疗经验。
5.Objective To compare the effects of three fixations for open tibiofibula fractures.
目的比较开放性胫腓骨骨折三种不同固定方法的疗效。
6.During the surgery, the surgeon had to realign the tibiofibula 胫腓骨 to ensure proper healing.
在手术过程中,外科医生必须重新对齐胫腓骨 以确保正确愈合。
7.The doctor explained that the fracture was located in the tibiofibula 胫腓骨 region.
医生解释说,骨折位于胫腓骨 区域。
8.The veterinarian noted that the injury involved the tibiofibula 胫腓骨 of the animal’s leg.
兽医指出,伤害涉及动物腿部的胫腓骨 。
9.In some species, the tibiofibula 胫腓骨 is fused for better stability.
在某些物种中,胫腓骨 融合以提供更好的稳定性。
10.The tibiofibula 胫腓骨 plays a crucial role in weight-bearing activities.
在承重活动中,胫腓骨 起着至关重要的作用。
作文
The human body is a complex and fascinating system, composed of various bones, muscles, and tissues that work together to enable movement and provide structure. Among the many bones in our body, one particularly interesting aspect is the relationship between the tibia and fibula, which are two long bones located in the lower leg. In some animals, these two bones can be fused into a single structure known as the tibiofibula, or in Chinese, 胫腓骨. This fusion presents unique adaptations that allow for different forms of locomotion and stability. In humans, the tibia, or shinbone, is the larger and stronger of the two bones, while the fibula is thinner and runs parallel to the tibia. Together, they support the weight of the body and play crucial roles in walking, running, and jumping. However, in certain species, especially among some reptiles and amphibians, the tibiofibula serves as an evolutionary advantage. The fusion of these bones can lead to a more robust structure that enhances the animal's ability to move efficiently across various terrains.The concept of bone fusion is not limited to just the tibiofibula. In fact, many other animals exhibit similar adaptations where certain bones merge to create a stronger, more functional limb. For example, birds have fused bones in their wings that enable them to fly with greater ease and stability. This adaptation highlights the incredible versatility of skeletal structures in response to environmental demands.Studying the tibiofibula in various species can provide insights into how different organisms adapt to their environments. Researchers in the fields of biology and paleontology often examine fossilized remains to understand how ancient creatures moved and interacted with their surroundings. By analyzing the structure of the tibiofibula in these fossils, scientists can infer patterns of behavior, locomotion, and even the ecological niches these animals occupied.Additionally, understanding the tibiofibula is significant in the field of medicine. Injuries to the tibia and fibula are common, particularly in athletes and active individuals. Fractures in these bones can lead to complications that require careful management and rehabilitation. Knowledge about the anatomy and function of the tibiofibula can aid medical professionals in diagnosing and treating such injuries effectively.In conclusion, the tibiofibula represents an intriguing aspect of vertebrate anatomy that illustrates the diversity of skeletal adaptations across species. Its study not only enhances our understanding of evolutionary biology but also contributes to practical applications in medicine and rehabilitation. As we continue to explore the complexities of the skeletal system, the tibiofibula serves as a reminder of the intricate connections between form, function, and survival in the animal kingdom.
人体是一个复杂而迷人的系统,由各种骨骼、肌肉和组织组成,这些部分共同作用以实现运动并提供结构。在我们身体的许多骨骼中,有一个特别有趣的方面是胫骨和腓骨之间的关系,这两根长骨位于小腿部。 在某些动物中,这两根骨头可以融合成一个称为tibiofibula的单一结构,中文为胫腓骨。这种融合呈现出独特的适应性,使得不同形式的运动和稳定性得以实现。在人体中,胫骨或称为小腿骨,是两根骨头中较大且更强的一根,而腓骨则较细,与胫骨平行。它们共同支撑着身体的重量,并在行走、奔跑和跳跃中发挥关键作用。然而,在某些物种中,特别是在一些爬行动物和两栖动物中,tibiofibula作为一种进化优势存在。这些骨头的融合可以导致更坚固的结构,从而增强动物在各种地形上高效移动的能力。骨融合的概念并不仅限于tibiofibula。事实上,许多其他动物表现出类似的适应性,其中某些骨头合并以创造出更强大、更具功能性的肢体。例如,鸟类的翅膀中有融合的骨头,使它们能够更轻松和稳定地飞行。这种适应性突显了骨骼结构在应对环境需求时的巨大多样性。研究各种物种中的tibiofibula可以为我们提供不同生物如何适应其环境的见解。生物学和古生物学领域的研究人员经常检查化石遗骸,以了解古代生物如何移动和与其环境互动。通过分析这些化石中tibiofibula的结构,科学家可以推断出行为模式、运动方式,甚至这些动物所占据的生态位。此外,了解tibiofibula在医学领域也很重要。胫骨和腓骨的损伤很常见,尤其是在运动员和活跃个体中。这些骨头的骨折可能导致需要仔细管理和康复的并发症。关于tibiofibula的解剖学和功能的知识可以帮助医疗专业人员有效地诊断和治疗此类伤害。总之,tibiofibula代表了脊椎动物解剖学的一个引人入胜的方面,说明了不同物种之间骨骼适应性的多样性。它的研究不仅增强了我们对进化生物学的理解,还为医学和康复的实际应用做出了贡献。随着我们继续探索骨骼系统的复杂性,tibiofibula提醒我们动物王国中形式、功能和生存之间的微妙联系。
