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Name | IPTG from plant origin galactose, dioxane free |
Source | Plant origin - galactose |
Purity | High purity |
Form | Powder |
Solubility | Soluble in water |
Storage | Store at room temperature |
Stability | Stable under recommended storage conditions |
Appearance | White to off-white solid |
Molecular Weight | 238.30 g/mol |
Melting Point | 180-182°C |
Usage | Inducer of lac operon in molecular biology research |
Availability | Commercially available |
FAQ
What is IPTG and how is it used in research settings?
IPTG, or Isopropyl β-D-1-thiogalactopyranoside, is a widely used chemical compound in molecular biology and biotechnology research. It is a molecular mimic of lactose that is not metabolized by the lac operon, making it an ideal inducer for the lac system in prokaryotic organisms such as E. coli. IPTG is commonly used to induce protein expression from a plasmid containing a lac operator, allowing for tight control over gene expression levels in experimental settings.
What are the benefits of using IPTG from plant origin?
IPTG from plant origin offers several advantages compared to synthetic sources. Plant-derived IPTG is often purer and more environmentally friendly, as it is produced using natural processes without the use of harsh chemicals. Additionally, plant-derived IPTG is free from contaminants such as dioxane, making it a safer choice for cell culture and other sensitive applications. Overall, IPTG from plant origin provides researchers with a high-quality inducer that meets their research needs while reducing environmental impact.
How is IPTG from plant origin produced?
IPTG from plant origin is typically produced using plant-based raw materials through a series of purification steps. The process begins with the extraction of galactose, a natural sugar found in plants, which is then chemically modified to create IPTG. The final product is carefully purified to remove impurities and ensure high quality and purity. By utilizing plant-derived raw materials, manufacturers can produce IPTG in an environmentally sustainable manner while maintaining the high standards required for research applications.
What sets plant-origin IPTG apart from synthetic alternatives?
Plant-origin IPTG offers several key advantages over synthetic alternatives. Firstly, plant-derived IPTG is produced using renewable resources and sustainable practices, reducing the environmental impact of its production. Additionally, plant-origin IPTG is free from dioxane and other harmful contaminants commonly found in synthetic inducers, making it safer for use in cell culture and other sensitive applications. The use of plant-derived raw materials also ensures a high level of purity and quality in the final product, providing researchers with a reliable inducer for their experiments.
How can researchers benefit from using plant-origin IPTG?
Researchers can benefit from using plant-origin IPTG in a variety of experimental settings. Plant-derived IPTG offers a pure and uncontaminated inducer for protein expression studies, ensuring accurate and reliable results. Its environmentally friendly production process also aligns with the growing demand for sustainable research practices. By choosing plant-origin IPTG, researchers can support sustainable sourcing practices while utilizing a high-quality inducer for their molecular biology experiments.
IPTG, or Isopropyl β-D-1-thiogalactopyranoside, is a widely used chemical compound in molecular biology and biotechnology research. It is a molecular mimic of lactose that is not metabolized by the lac operon, making it an ideal inducer for the lac system in prokaryotic organisms such as E. coli. IPTG is commonly used to induce protein expression from a plasmid containing a lac operator, allowing for tight control over gene expression levels in experimental settings.
What are the benefits of using IPTG from plant origin?
IPTG from plant origin offers several advantages compared to synthetic sources. Plant-derived IPTG is often purer and more environmentally friendly, as it is produced using natural processes without the use of harsh chemicals. Additionally, plant-derived IPTG is free from contaminants such as dioxane, making it a safer choice for cell culture and other sensitive applications. Overall, IPTG from plant origin provides researchers with a high-quality inducer that meets their research needs while reducing environmental impact.
How is IPTG from plant origin produced?
IPTG from plant origin is typically produced using plant-based raw materials through a series of purification steps. The process begins with the extraction of galactose, a natural sugar found in plants, which is then chemically modified to create IPTG. The final product is carefully purified to remove impurities and ensure high quality and purity. By utilizing plant-derived raw materials, manufacturers can produce IPTG in an environmentally sustainable manner while maintaining the high standards required for research applications.
What sets plant-origin IPTG apart from synthetic alternatives?
Plant-origin IPTG offers several key advantages over synthetic alternatives. Firstly, plant-derived IPTG is produced using renewable resources and sustainable practices, reducing the environmental impact of its production. Additionally, plant-origin IPTG is free from dioxane and other harmful contaminants commonly found in synthetic inducers, making it safer for use in cell culture and other sensitive applications. The use of plant-derived raw materials also ensures a high level of purity and quality in the final product, providing researchers with a reliable inducer for their experiments.
How can researchers benefit from using plant-origin IPTG?
Researchers can benefit from using plant-origin IPTG in a variety of experimental settings. Plant-derived IPTG offers a pure and uncontaminated inducer for protein expression studies, ensuring accurate and reliable results. Its environmentally friendly production process also aligns with the growing demand for sustainable research practices. By choosing plant-origin IPTG, researchers can support sustainable sourcing practices while utilizing a high-quality inducer for their molecular biology experiments.