関: malonate

WordNet

street name for lysergic acid diethylamide (同)back breaker, battery-acid, dose, dot, Elvis, loony toons, Lucy in the sky with diamonds, pane, superman, window pane, Zen
any of various water-soluble compounds having a sour taste and capable of turning litmus red and reacting with a base to form a salt
having the characteristics of an acid; "an acid reaction"

PrepTutorEJDIC

酸性の / 酸味のある,すっぱい(sour) / (言葉・態度などが)厳しい,しんらつな / 酸 / すっぱいもの / 《俗》=LSD

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出典(authority):フリー百科事典『ウィキペディア（Wikipedia）』「2015/12/09 05:32:24」(JST)

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Malonic acid (IUPAC systematic name: propanedioic acid) is a dicarboxylic acid with structure CH₂(COOH)₂. The ionized form of malonic acid, as well as its esters and salts, are known as malonates. For example, diethyl malonate is malonic acid's diethyl ester. The name originates from the Greek word μᾶλον (malon) meaning 'apple'.

Biochemistry

The calcium salt of malonic acid occurs in high concentrations in beetroot. It exists in its normal state as white crystals. Malonic acid is the classic example of a competitive inhibitor: It acts against succinate dehydrogenase^[2] (complex II) in the respiratory electron transport chain.

Preparation

A classical preparation of malonic acid starts from chloroacetic acid:^[3]

Preparation of malonic acid from chloroacetic acid.

Sodium carbonate generates the sodium salt, which is then reacted with sodium cyanide to provide the cyano acetic acid salt via a nucleophilic substitution. The nitrile group can be hydrolyzed with sodium hydroxide to sodium malonate, and acidification affords malonic acid.

Malonic acid was first prepared in 1858 by the French chemist Victor Dessaignes (1800-1885) via the oxidation of malic acid.^[4]

More recently, malonic acid has been produced through fermentation of glucose from renewable feedstock and purification of raw bio-based malonic acid. This higher yielding route could offer environmental benefits via elimination of cyanide and chloroacetic acid use in addition to carbon sequestration.^[5]

Organic reactions

In a well-known reaction, malonic acid condenses with urea to form barbituric acid. Malonic acid is also frequently used as an enolate in Knoevenagel condensations or condensed with acetone to form Meldrum's acid. The esters of malonic acid are also used as a ⁻CH₂COOH synthon in the malonic ester synthesis.

Additionally, the coenzyme A derivative of malonate, malonyl-CoA, is an important precursor in fatty acid biosynthesis along with acetyl CoA. Malonyl CoA is formed from acetyl CoA by the action of acetyl-CoA carboxylase, and the malonate is transferred to an acyl carrier protein to be added to a fatty acid chain.

Malonic acid is also known to be a competitive inhibitor of succinic dehydrogenase, the enzyme responsible for the dehydrogenation of succinate within Krebs cycle.

Applications

Malonic acid is a precursor to specialty polyesters. It can be converted into 1,3 propanediol for use in polyesters and polymers and a projected market size of $621.2 million by 2021. It can also be a component in alkyd resins, which are used in a number of coatings applications for protecting against damage caused by UV light, oxidation, and corrosion. One application of malonic acid is in the coatings industry as a crosslinker for low-temperature cure powder coatings, which are becoming increasingly valuable for heat sensitive substrates and a desire to speed up the coatings process. ^[6] The global coatings market for automobiles was estimated to be $18.59 billion in 2014 with projected combined annual growth rate of 5.1% through 2022. ^[7]

It is used in a number of manufacturing processes as a high value specialty chemical including the electronics industry, flavors and fragrances industry, specialty solvents, polymer crosslinking, and pharmaceutical industry. Global production of malonic acid and its malonate ester derivatives is estimated at 16,000 to 20,000 metric tons per year. Potential growth of these markets could result from advances in industrial biotechnology that seeks to displace petroleum-based chemicals in industrial applications. Malonic acid was listed as one of the top 30 chemicals to be produced from biomass by the US Department of Energy.^[8] In food and drug applications, malonic acid can be used to control acidity, either as an excipient in pharmaceutical formulation or natural preservative additive for foods.

Malonic acid is used as a building block chemical to produce numerous valuable compounds.^[9]

Most recently, malonic acid has been used to produce an enhanced starch-based resin, which is environmentally-benign, uses water-based processing without toxic catalysts.^[10]

Eastman Kodak company and others use malonic acid and derivatives as a surgical adhesive.^[11]

References

^ ^a ^b pKa Data Compiled by R. Williams (pdf; 77 kB)
^ Pardee, Arthur B.; Potter, Van R. (26 October 1948). "Malonate Inhibition of Oxidations in the Krebs Tricarboxylic Acid Cycle" (PDF). Journal of Biological Chemistry (178): 241–250. Retrieved 5 June 2015.
^ Nathan Weiner. "Malonic acid". Org. Synth. ; Coll. Vol. 2, p. 376
^ See:
- Dessaignes (1858) "Note sur un acide obtenu par l'oxydation de l'acide malique" (Note on an acid obtained by oxidation of malic acid), Comptes rendus, 47 : 76-79.
- Dessaignes (1858) "Ueber eine durch Oxydation der Aepfelsäure erhaltene Säure" (On an acid obtained by oxidation of malic acid) Annalen der Chemie und Pharmacie, 107 : 251-254.
^ See:
- Recombinant host cells for the production of malonate. PCT/US2013/029441 2012.
^ Fäcke, T., Subramanian R., Dvorchak, M., Feng, S. Diethylmalonate Blocked Isocyanates As Crosslinkers For Low Temperature Cure Powder Coatings. 2004 International Waterborne, High-Solids, and Powder Coatings Symposium.
^ James, S. Global Automotive Coatings Market. 2015 Grand View Research Market Report
^ Werpy, T., Petersen, G. Top Value Added Chemicals from Biomass. 2004 US Department of Energy.
^ Hildbrand, S.; Pollak, P. Malonic Acid & Derivatives. March 15, 2001. Ullmann's Encyclopedia of Industrial Chemistry
^ Netravali, A., Dastidar, T. Crosslinked native and waxy starch resin compositions and processes for their manufacture. 2013 US. Appl No. 14/418,940.
^ Hawkins, G., Fassett, D. Surgical Adhesive Compositions. 1971 US Patent No. 3,591,676.

External links

pH-Spectrum of Disodium Malonate
pH-Spectrum of Malonate-copper-complex
Calculator: Water and solute activities in aqueous malonic acid
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English Journal

Photodegradation of parabens by Fe(III)-citrate complexes at circumneutral pH: Matrix effect and reaction mechanism.

Feng X1, Chen Y2, Fang Y1, Wang X3, Wang Z1, Tao T1, Zuo Y4.Author information 1School of Environmental Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, China.2School of Environmental Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, China. Electronic address: ychen@hust.edu.cn.3Huazhong University of Science and Technology Wenhua College, Wuhan 430074, China.4Department of Chemistry & Biochemistry, University of Massachusetts Dartmouth, North Dartmouth, MA 02747, United States.AbstractThe photodegradation of four parabens including methyl-, ethyl-, propyl-, and butyl-paraben in the presence of Fe(III)-citrate complexes under simulated sunlight was investigated. The degradation of parabens increased with decreasing pH within the range of 5.0-8.0 at the Fe(III)-to-citrate ratio of 10:150 (μM). The addition of low-molecular-weight carboxylic acids showed different effects on the photodegradation of methylparaben. The low-photoreactive carboxylic acids inhibited the photodegradation of methylparaben in the order of formic acid>succinic acid>acetic acid>malonic acid. In contrast, oxalic acid enhanced the photodegradation and exhibited appreciable synergistic effect with Fe(III)-citrate at concentration higher than 500μM. Up to 99.0% of substrate was degraded after 30min at pH6.0 in the Fe(III)-citrate-oxalate system. The various fractions of fulvic acid inhibited the photodegradation of methylparaben. The inhibition increased with increasing nominal molecular weight of fractionated fulvic acid. Moreover, the photodegradation of methylparaben was inhibited in natural waters in the order of Liangzi Lake<Donghu Lake<Changjiang River≈Seawater. The photoproducts of methylparaben were identified by GC-MS analyses and the degradation pathway was proposed.
The Science of the total environment.Sci Total Environ.2014 Feb 15;472:130-6. doi: 10.1016/j.scitotenv.2013.11.005. Epub 2013 Nov 27.
The photodegradation of four parabens including methyl-, ethyl-, propyl-, and butyl-paraben in the presence of Fe(III)-citrate complexes under simulated sunlight was investigated. The degradation of parabens increased with decreasing pH within the range of 5.0-8.0 at the Fe(III)-to-citrate ratio of
PMID 24291138

A highly efficient in situ N-acetylation approach for solid phase synthesis.

Chandra K, Roy TK, Naoum JN, Gilon C, Gerber RB, Friedler A.Author information Institute of Chemistry, The Hebrew University of Jerusalem, Safra Campus, Givat Ram, Jerusalem 91904, Israel. assaf.friedler@mail.huji.ac.il.AbstractWe describe a new general N-acetylation method for solid phase synthesis. Malonic acid is used as a precursor and the reaction proceeds by in situ formation of a reactive ketene intermediate at room temperature. We have successfully applied this methodology to peptides and non-peptidic molecules containing a variety of functional groups. The reaction gave high yields compared to known acetylation methods, irrespective of the structure, conformation and sequence of the acetylated molecule. Computational studies revealed that the concerted mechanism via the ketene intermediate is kinetically favorable and leads to a thermodynamically stable acetylated product. In conclusion, our method can be easily applied to acetylation in a wide variety of chemical reactions performed on the solid phase.
Organic & biomolecular chemistry.Org Biomol Chem.2014 Feb 14. [Epub ahead of print]
We describe a new general N-acetylation method for solid phase synthesis. Malonic acid is used as a precursor and the reaction proceeds by in situ formation of a reactive ketene intermediate at room temperature. We have successfully applied this methodology to peptides and non-peptidic molecules con
PMID 24526269

Generative Force of Self-oscillating Gel.

Hara Y, Mayama H, Morishima K.AbstractWe succeeded in measuring the generative force of a self-oscillating polymer gel in an aqueous solution comprising the three substrates of the Belousov-Zhabotinsky (BZ) reaction (malonic acid, sodium bromate, and nitric acid) under constant temperature. In this study, we developed an apparatus with a microforce sensor for measuring the generative force of small-sized gels (1mm3). The self-oscillating polymer gel directly converts the chemical energy of the BZ reaction into mechanical work. It was determined that the generative force of the self-oscillating gel was 972 Pa, and the period of self-oscillation was 480 s at 18 °C. We demonstrated that the generative force of the gel was about a hundredth the generative force of a muscle in the body. We analyzed the time dependence of the color change in the self-oscillating polymer gel. The color of the gel changed periodically owing to the cyclic change in the redox state of the Ru moiety, induced by the BZ reaction. The peaks of the waveforms of the generative force and color change were almost identical. This result showed that the generative force was synchronized with the periodical change in the oxidation number of the Ru catalytic moiety in the gel. To understand a theoretical basis for the generative force of a self-oscillating gel, we considered a general theory that is based on the volume phase transition of gel and two parameter Oregonator model of the BZ reaction.
The journal of physical chemistry. B.J Phys Chem B.2014 Feb 13. [Epub ahead of print]
We succeeded in measuring the generative force of a self-oscillating polymer gel in an aqueous solution comprising the three substrates of the Belousov-Zhabotinsky (BZ) reaction (malonic acid, sodium bromate, and nitric acid) under constant temperature. In this study, we developed an apparatus with
PMID 24524539

Japanese Journal

Stability Order of Caffeine Co-crystals Determined by Co-crystal Former Exchange Reaction and Its Application for the Validation of in Silico Models

Mukaida Makoto,Sugano Kiyohiko,Terada Katsuhide
Chemical and Pharmaceutical Bulletin 63(1), 18-24, 2015
… When oxalic acid (OX) was added to CA–citric acid co-crystal (CA–CI), CA–CI converted to CA–OX, suggesting that CA–OX is more stable than CA–CI. … The stability order of CA co-crystals was determined as CA–OX≈CA–p-hydroxybenzoic acid (HY)>CA–CI>CA–malonic acid>CA–maleic acid. …
NAID 130004803752

Microbial Production of Novel Pigments from Black Rice Anthocyanin

Saigusa Noriaki,Yamamoto Keiko,Tsutsui Masahiko,Teramoto Yuji
Food Science and Technology Research 20(5), 1013-1016, 2014
… After culturing the microorganisms on PDA medium containing black rice anthocyanin, caffeic acid, p-hydroxybenzoic acid, ferulic acid, and malonic acid for 4 days at 30°C, one strain that changed the red medium to reddish purple was isolated. … Anthocyanins present in the color-changed medium were extracted using 15% (w/v) acetic acid and their absorption spectra were then determined. …
NAID 130004704881

The Effects of Interactions of Dicarboxylic Acids on the Stability of the Caffeine Molecule: A Theoretical Study

Azizi Abolfazl,Ebrahimi Ali,Habibi-Khorassani Mostafa [他],Rezazadeh Shiva,Behazin Roya
Bulletin of the Chemical Society of Japan 87(10), 1116-1123, 2014
… Caffeine, as a pharmaceutical compound, forms cocrystals with dicarboxylic acids through OH(acid)···N(caffeine) and CH(caffeine)···O(acid) hydrogen bonds. … In the present work, four 2:1 ternary complexes of the caffeine molecule with oxalic, malonic, maleic, and glutaric acids (as cocrystal units) were studied by computational quantum chemistry methods. …
NAID 130004153318

「マロン酸」

Malonic acid
Names
	IUPAC name propanedioic acid
	Other names methanedicarboxylic acid
Identifiers
CAS Number	141-82-2
ChEBI	CHEBI:30794
ChEMBL	ChEMBL7942
ChemSpider	844
DrugBank	DB02175
	InChI InChI=1S/C3H4O4/c4-2(5)1-3(6)7/h1H2,(H,4,5)(H,6,7) Key: OFOBLEOULBTSOW-UHFFFAOYSA-N ; InChI=1/C3H4O4/c4-2(5)1-3(6)7/h1H2,(H,4,5)(H,6,7) Key: OFOBLEOULBTSOW-UHFFFAOYAJ ;
Jmol interactive 3D	Image; Image
PubChem	867
	SMILES O=C(O)CC(O)=O ; C(C(=O)O)C(=O)O ;
Properties
Chemical formula	C3H4O4
Molar mass	104.06 g·mol−1
Density	1.619 g/cm3
Melting point	135 to 137 °C (275 to 279 °F; 408 to 410 K) (decomposes)
Boiling point	decomposes
Solubility in water	Miscible
Acidity (pKa)	pKa1 = 2.83; pKa2 = 5.69
Related compounds
Other anions	malonate
Related carboxylic acids	acetic acid; oxalic acid; propionic acid; tartronic acid; acrylic acid; butyric acid; succinic acid; fumaric acid
Related compounds	propanone; propionaldehyde; propanedial; dimethyl malonate
Hazards
Safety data sheet	External MSDS
	Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
	verify (what is ?)
	Infobox references