지식나눔

Metal reductant 사용 질문입니다.^^

안녕하세요.

metal reductant 사용에 관해 질문이 있어서 이렇게 글을 쓰게 되었습니다.

다름이 아니라, Iron powder가 팔던데.. 이것을 구매하여 사용하면 되는지요?

또 다른 문의는 Fe2+ -> Fe3+로 가면서 전자를 내놓게 되는데,,,

이게 별도의 다른 작용없이 가능한지도 여쭙습니다.

읽어주셔서 감사합니다.^^

좋은 하루 되십시오!
  • Reductant
지식의 출발은 질문, 모든 지식의 완성은 답변! 
각 분야 한인연구자와 현업 전문가분들의 답변을 기다립니다.
답변 3
  • 답변

    이배훈님의 답변

    Ammonium iron(II) sulfate hexahydrate ReagentPlus , ≥99%
    Iron(II) sulfate heptahydrate 
    ReagentPlus , ≥99.0%

    Primary Functions of Iron in Cell Culture Systems: 
    Iron is essential for cell respiration and metabolism. Without iron cells stop growing and eventually die. Iron can undergo univalent redox reactions. Its oxidized and reduced forms are referred to as ferric and ferrous iron, respectively.

     

    • Hemoglobin is the quantitatively predominant heme containing protein in mammals. Its primary function is to bind, transport, and release molecular oxygen. Hemoglobin bound iron remains in the ferrous state during oxygen binding, transport and release. When hemoglobin bound iron is oxidized to ferric iron, it cannot transport oxygen. Oxidized hemoglobin is called methemoglobin.
    • Cytochromes are a group of heme containing proteins located in the mitochondria. Their function is the sequential transfer of electrons along the respiratory chain leading to reduction of oxygen to water, and the storage of energy in the form of ATP. The transfer of electrons by cytochromes involves oxidation and reduction cycling of iron.
    • Iron exists in a non-heme form as part of succinate dehydrogenase (EC 1.3.99.1), an enzyme that catalyses the formation of fumarate.
    • As an enzyme cofactor, iron protects cells from oxidative damage. It exists as a heme component of enzymes such as catalase and peroxidase that catalyze the conversion of peroxides to water.

    Iron, a Serum-Free Medium Supplement, Useful In Biomanufacturing; Tissue Engineering and Specialty Media: 
    Iron is an essential transition metal in cell culture. It has both beneficial and toxic properties. Consequently, the management of iron levels and delivery are a major challenge. The natural physiological delivery of iron to cells in culture is mediated by transferrin when serum is used. The development of serum-free, animal-protein- and protein-free media has greatly increased the potential for iron toxicity in culture. This is especially critical in biomanufacturing and tissue engineering where iron mediated oxidative and carbonyl stress can alter the chemistry of a cell culture product.

    The classical and commercially available media can be divided roughly into three groups: those that do not have iron in the basal formulation: Ames' Medium; Basal Medium Eagle (BME); BGJb Medium Fitton-Jackson Modification; Click's Medium; CMRL-1066 Medium: Fischer's Medium; Iscove's Modified Dulbecco's Medium (IMDM); L-15; McCoy's 5A Modified Medium; Medium 199; RPMI-1640; Swim's S-77 Medium; Waymouth Medium MB; those that contain ferric nitrate: Dulbecco's Modified Eagle's Medium (DMEM); Glascow Modified Eagle's Medium (GMEM); H-Y Medium (Hybri-Max®); Medium 199; and Williams Medium E; and those that contain ferrous sulfate (generally based on Ham's Nutrient Mixtures): F-12 Coon's Modification; Nutrient Mixture, Ham's F-10; Nutrient Mixture, Ham's F-12; Nutrient Mixture, Ham's F-12 Kaighn's Modification (F12K); MCDB Media; and Serum-Free/Protein Free Hybridoma Medium.

    DMEM/Ham's Nutrient Mixture F-12 (50:50) contains both ferric nitrate and ferrous sulfate.

    A number of media used as the basis for development of proprietary media useful in biomanufacturing and tissue engineering do not contain iron in their formulae or have been re-engineered specifically to manage iron delivery and toxicity. Proprietaty media developed from Dulbecco's Modified Eagle's Medium (DMEM); Nutrient Mixture, Ham's F-12; and DMEM/Ham's Nutrient Mixture F-12 (50:50) or any other inorganic iron supplemented media typically have the iron salts removed and replaced by a chelated iron. Other important basal media for proprietary media development such as Iscove's Modified Dulbecco's Medium (IMDM) are generally supplemented with a chelated iron.

    The management of iron delivery is one of the most complex, yet important, requirements for the development of a suitable cell culture system for biomanufacturing and tissue engineering. Improper iron management affects not only the cell, but also the quality of the cell product. For a more complete discussion of chelated-iron as a cell culture additive go to Sigma's Media Expert.



    Iron in Cell Culture
    Ammonium iron(II) sulfate hexahydrate ReagentPlus , ≥99%
    Iron(II) sulfate heptahydrate 
    ReagentPlus , ≥99.0%

    Primary Functions of Iron in Cell Culture Systems: 
    Iron is essential for cell respiration and metabolism. Without iron cells stop growing and eventually die. Iron can undergo univalent redox reactions. Its oxidized and reduced forms are referred to as ferric and ferrous iron, respectively.

     

    • Hemoglobin is the quantitatively predominant heme containing protein in mammals. Its primary function is to bind, transport, and release molecular oxygen. Hemoglobin bound iron remains in the ferrous state during oxygen binding, transport and release. When hemoglobin bound iron is oxidized to ferric iron, it cannot transport oxygen. Oxidized hemoglobin is called methemoglobin.
    • Cytochromes are a group of heme containing proteins located in the mitochondria. Their function is the sequential transfer of electrons along the respiratory chain leading to reduction of oxygen to water, and the storage of energy in the form of ATP. The transfer of electrons by cytochromes involves oxidation and reduction cycling of iron.
    • Iron exists in a non-heme form as part of succinate dehydrogenase (EC 1.3.99.1), an enzyme that catalyses the formation of fumarate.
    • As an enzyme cofactor, iron protects cells from oxidative damage. It exists as a heme component of enzymes such as catalase and peroxidase that catalyze the conversion of peroxides to water.

    Iron, a Serum-Free Medium Supplement, Useful In Biomanufacturing; Tissue Engineering and Specialty Media: 
    Iron is an essential transition metal in cell culture. It has both beneficial and toxic properties. Consequently, the management of iron levels and delivery are a major challenge. The natural physiological delivery of iron to cells in culture is mediated by transferrin when serum is used. The development of serum-free, animal-protein- and protein-free media has greatly increased the potential for iron toxicity in culture. This is especially critical in biomanufacturing and tissue engineering where iron mediated oxidative and carbonyl stress can alter the chemistry of a cell culture product.

    The classical and commercially available media can be divided roughly into three groups: those that do not have iron in the basal formulation: Ames' Medium; Basal Medium Eagle (BME); BGJb Medium Fitton-Jackson Modification; Click's Medium; CMRL-1066 Medium: Fischer's Medium; Iscove's Modified Dulbecco's Medium (IMDM); L-15; McCoy's 5A Modified Medium; Medium 199; RPMI-1640; Swim's S-77 Medium; Waymouth Medium MB; those that contain ferric nitrate: Dulbecco's Modified Eagle's Medium (DMEM); Glascow Modified Eagle's Medium (GMEM); H-Y Medium (Hybri-Max®); Medium 199; and Williams Medium E; and those that contain ferrous sulfate (generally based on Ham's Nutrient Mixtures): F-12 Coon's Modification; Nutrient Mixture, Ham's F-10; Nutrient Mixture, Ham's F-12; Nutrient Mixture, Ham's F-12 Kaighn's Modification (F12K); MCDB Media; and Serum-Free/Protein Free Hybridoma Medium.

    DMEM/Ham's Nutrient Mixture F-12 (50:50) contains both ferric nitrate and ferrous sulfate.

    A number of media used as the basis for development of proprietary media useful in biomanufacturing and tissue engineering do not contain iron in their formulae or have been re-engineered specifically to manage iron delivery and toxicity. Proprietaty media developed from Dulbecco's Modified Eagle's Medium (DMEM); Nutrient Mixture, Ham's F-12; and DMEM/Ham's Nutrient Mixture F-12 (50:50) or any other inorganic iron supplemented media typically have the iron salts removed and replaced by a chelated iron. Other important basal media for proprietary media development such as Iscove's Modified Dulbecco's Medium (IMDM) are generally supplemented with a chelated iron.

    The management of iron delivery is one of the most complex, yet important, requirements for the development of a suitable cell culture system for biomanufacturing and tissue engineering. Improper iron management affects not only the cell, but also the quality of the cell product. For a more complete discussion of chelated-iron as a cell culture additive go to Sigma's Media Expert.



    Iron in Cell Culture
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    신동협님의 답변

    금속은 reducing agent 입니다. 아시다시피 금속은 electropositive하기 때문에
    전자를 다른 원소에 제공하게 됩니다. 그리고 파우더 형태의 금속 입자는
    표면적이 넓어서 반응성이 더 좋을 것으로 생각됩니다. 반대로 실험하기 전에
    산화될 수도 있으니 잘 관리하셔야 할 것 같습니다.
     
    금속은 reducing agent 입니다. 아시다시피 금속은 electropositive하기 때문에
    전자를 다른 원소에 제공하게 됩니다. 그리고 파우더 형태의 금속 입자는
    표면적이 넓어서 반응성이 더 좋을 것으로 생각됩니다. 반대로 실험하기 전에
    산화될 수도 있으니 잘 관리하셔야 할 것 같습니다.
     
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    안길홍님의 답변

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