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相关概念视频

Energy Budgets and Reproductive Strategies00:51

Energy Budgets and Reproductive Strategies

Organisms must balance energy intake with the energy required for growth, maintenance, and reproduction. These trade-offs result in a variety of survivorship and reproductive strategies, including semelparity and iteroparity. Semelparous species reproduce only once in their lifetime, often investing most available resources into that single reproductive event. Iteroparous species, by contrast, reproduce multiple times over their lifetimes, typically allocating fewer resources to any single...
Production Efficiency01:01

Production Efficiency

Net production efficiency (NPE) is the efficiency at which organisms assimilate energy into biomass for the next trophic level. Due to low metabolic rates and less energy spent on thermoregulatory processes, the NPE of ectotherms (cold-blooded animals) is 10 times higher than endotherms (warm-blooded animals).
Trophic Efficiency00:46

Trophic Efficiency

Trophic level transfer efficiency (TLTE) is a measure of the total energy transfer from one trophic level to the next. Due to extensive energy loss as metabolic heat, an average of only 10% of the original energy obtained is passed on to the next level. This pattern of energy loss severely limits the possible number of trophic levels in a food chain.
Optimal Foraging00:48

Optimal Foraging

How animals obtain and eat their food is called foraging behavior. Foraging can include searching for plants and hunting for prey and depends on the species and environment.
Metabolic Rate01:25

Metabolic Rate

The human body is a powerhouse of energy, with every cell performing numerous functions that require energy. This energy production and consumption is measured by the metabolic rate, which quantifies the total heat generated by all the body's chemical reactions and mechanical work. This measurement helps to determine the rate of kilocalorie (kcal) consumption needed to fuel all ongoing activities.
The Basal Metabolic Rate (BMR) measures the energy expended at rest.
Several factors influence the...
Oxygen Requirements and Growth Patterns01:29

Oxygen Requirements and Growth Patterns

Microorganisms exhibit diverse oxygen requirements and growth patterns driven by their metabolic strategies and environmental adaptations. Oxygen, while essential for many organisms, can also be toxic under certain conditions, shaping how microorganisms grow and survive.Oxygen Requirements of MicroorganismsMicroorganisms are classified based on their ability to use or tolerate oxygen:● Obligate aerobes like Mycobacterium tuberculosis need oxygen for energy production, as it serves as the...

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相关实验视频

Updated: Jun 28, 2026

Development of a Mobile Mitochondrial Physiology Laboratory for Measuring Mitochondrial Energetics in the Field
08:54

Development of a Mobile Mitochondrial Physiology Laboratory for Measuring Mitochondrial Energetics in the Field

Published on: August 27, 2021

在体生过程中能量吸收和分配.

Chen Hou1, Wenyun Zuo, Melanie E Moses

  • 1Santa Fe Institute, 1399 Hyde Park Road, Santa Fe, NM 87501, USA. houc@santafe.edu

Science (New York, N.Y.)
|November 1, 2008
PubMed
概括

根据一个新的模型,成长中的动物有效地分配食物能量用于生物质的合成和维护. 该框架协调了以前的能源预算方法,揭示了动物生长和同化的普遍原则.

科学领域:

  • 动物学 动物学
  • 身体生理学 身体生理学
  • 生态生态学 生态生态学

背景情况:

  • 生物体需要能量来进行体质生长,因此需要在生物质合成和维护之间进行分配.
  • 现有的能源预算模型侧重于食物消费或代谢支出,限制了统一的理解.
  • 在协调这些方法来解释生长动物的能量分配策略方面存在差距.

研究的目的:

  • 介绍一种用于预测生长动物能量分配的新型模型.
  • 通过将食品消费和代谢支出整合起来,使以前的能源预算模型相协调.
  • 确定管理食物同化和能量分割的基本原则.

主要方法:

  • 使用鸟类和哺乳动物的数据开发了一个经验基础的模型.
  • 食品消费和代谢能量消耗的综合概念.
  • 分析了用于维护,生物合成,活动和储存的能量分配.

主要成果:

  • 该模型准确地预测了成长中的动物如何在生物质合成和维护之间分配食物能量.
  • 该框架协调了能源预算建模的不同方法.
  • 预测动物生长和同化率的普遍曲线.
  • 来自各种鸟类和哺乳动物的经验数据支持该模型的预测.

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Determining Basal Energy Expenditure and the Capacity of Thermogenic Adipocytes to Expend Energy in Obese Mice
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Determining Basal Energy Expenditure and the Capacity of Thermogenic Adipocytes to Expend Energy in Obese Mice

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Quantification of Macronutrients Intake in a Thermogenetic Neuronal Screen using Drosophila Larvae
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Development of a Mobile Mitochondrial Physiology Laboratory for Measuring Mitochondrial Energetics in the Field
08:54

Development of a Mobile Mitochondrial Physiology Laboratory for Measuring Mitochondrial Energetics in the Field

Published on: August 27, 2021

Determining Basal Energy Expenditure and the Capacity of Thermogenic Adipocytes to Expend Energy in Obese Mice
06:57

Determining Basal Energy Expenditure and the Capacity of Thermogenic Adipocytes to Expend Energy in Obese Mice

Published on: November 11, 2021

Quantification of Macronutrients Intake in a Thermogenetic Neuronal Screen using Drosophila Larvae
07:24

Quantification of Macronutrients Intake in a Thermogenetic Neuronal Screen using Drosophila Larvae

Published on: June 11, 2020

结论:

  • 拟议的模型为理解动物能源预算提供了一个统一的框架.
  • 动物的生长和同化率似乎遵循了普遍的模式.
  • 这些发现对动物学,生理学和生态学有着广泛的影响.