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相关概念视频

Microbial Growth Measurement: Direct Methods01:23

Microbial Growth Measurement: Direct Methods

Direct methods for measuring microbial populations in a culture are essential tools in microbiology, providing quantitative data for various applications. Among these, microscopic counts, plate counts, and serial dilution are widely used techniques, each with unique principles and applications.Microscopic CountsMicroscopic counting involves the use of a Petroff-Hausser chamber, a specialized microscope slide with a grid and defined depth. By observing a liquid culture under a microscope,...
Microbial Growth Measurement: Indirect Methods01:27

Microbial Growth Measurement: Indirect Methods

Estimating microbial growth is essential for understanding population dynamics and environmental adaptations. Indirect methods provide valuable insights by measuring parameters such as turbidity, metabolic activity, and biomass, enabling efficient and reproducible assessments.During exponential growth, microbial cells scatter light proportionally to their biomass, a principle used in turbidity measurements. About one million cells per milliliter produce detectable scattering, which a...
Methods for Controlling Microbial Growth01:29

Methods for Controlling Microbial Growth

Microbial growth control refers to various methods employed to inhibit, reduce, or eliminate microorganisms to ensure safety and hygiene across different settings. These methods are categorized based on the target environment and the level of microbial control required.Biocides are versatile agents designed to control microorganisms by either inhibiting their growth or outright killing them. These agents work through various physical, chemical, mechanical, or biological mechanisms. The...
Methods to Assess Microbial Populations01:30

Methods to Assess Microbial Populations

Assessing microbial populations is crucial for understanding microbial roles in health, ecology, and industry. Various complementary techniques—both culture-based and molecular—enable detailed analysis of microbial abundance, diversity, and function.Viable Plate CountThe viable plate count is a traditional culture-based method used to estimate the number of living microbes in a sample. After serial dilution, the sample is spread onto nutrient agar plates. Each viable cell forms a visible...

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相关实验视频

Updated: Jun 21, 2026

A Microfluidic Device for Studying Multiple Distinct Strains
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在动态环境中使用微流体单细胞培养量化微生物强度.

Luisa Blöbaum1,2, Luca Torello Pianale3, Lisbeth Olsson3

  • 1Multiscale Bioengineering, Technical Faculty, Bielefeld University, Bielefeld, Germany.

Microbial cell factories
|February 9, 2024
PubMed
概括

使用动态微流体单细胞培养 (dMSCC) 和新型管道评估了微生物对环境变化的强度. 较长的葡萄糖周期增加了ATP水平,但降低了稳定性并增加了细胞异质性.

关键词:
生物传感器是一种生物传感器.动态环境 动态环境活细胞成像成像技术微流体单细胞培养方法营养物质振荡的振荡人口异质性 人口异质性这种植物是Saccharomyces cerevisiae.缩小规模的降低.

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科学领域:

  • 微生物学 微生物学
  • 生物技术是生物技术.
  • 系统生物学 系统生物学

背景情况:

  • 微生物功能稳定性对于实验室和工业应用至关重要.
  • 评估对动态环境变化的强度是具有挑战性的.
  • 动态微流体单细胞培养 (dMSCC) 提供精确的环境控制和单细胞跟踪.

研究的目的:

  • 开发和应用一个结合dMSCC和强度量化的管道,用于微生物功能稳定性分析.
  • 在动态葡萄糖盛宴-饥饿周期下调查Saccharomyces cerevisiae的性能和稳健性.
  • 评估群体,亚群体和单细胞水平上的微生物反应.

主要方法:

  • 将dMSCC与稳定性量化方法的整合.
  • 开发一个半自动图像和数据分析管道.
  • 暴露Saccharomyces cerevisiae在20小时内从1.5分钟到48分钟的葡萄糖振荡.

主要成果:

  • 特定生长率随着振荡间隔的延长而下降.
  • 细胞内ATP水平随着振荡间隔的延长而增加.
  • 48分钟的振荡产生了最高的平均ATP,但稳定性最低,异质性最高.

结论:

  • 开发的管道允许在动态环境中对微生物功能稳定性的强有力的研究.
  • 该策略是可自动化,可并行化和适应各种生物和条件的.
  • 结果将指导微生物菌株的发展和生物过程的优化.