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DMTMM

4-(4,6-Dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium (CAS 3945-69-5), commonly abbreviated as DMTMM, is a triazine-derived uronium employed as a versatile condensing agent in . It enables the activation of carboxylic acids to form reactive intermediates, facilitating the direct coupling with amines to produce , as well as esters and glycosidic bonds, under mild conditions with minimal . First reported in 1999, DMTMM has become a preferred reagent for amide bond formation due to its and compatibility with protic solvents like , , and , where traditional carbodiimides often fail. DMTMM is synthesized quantitatively by reacting 2-chloro-4,6-dimethoxy-1,3,5-triazine (CDMT) with in (THF) at , yielding a after precipitation. The compound appears as a white, non-hygroscopic, shelf-stable solid that remains effective for at least one month at , though is recommended for long-term storage to prevent slow decomposition. It exhibits slight solubility in and (DMSO), and its reactions proceed efficiently in aqueous or alcoholic media without requiring conditions. Upon completion, DMTMM decomposes into non-toxic byproducts, including 2,4-dimethoxy-6-hydroxy-1,3,5-triazine (DMTOH) and a tertiary , enhancing its appeal for sustainable chemistry. In applications, DMTMM excels in peptide synthesis, both in solution and on solid supports, where it promotes high-yield couplings with low epimerization rates, making it superior to alternatives like EDC/NHS for sensitive substrates such as hyaluronan derivatives. It has been utilized in the modification of biopolymers, including the cross-linking of collagen and the preparation of carboxymethylcellulose films, as well as the grafting of amines onto chitosan, and in the preparation of 1,2,4-oxadiazoles from amidoximes. Its robustness in biorelevant systems, such as saccharides and nucleotides, underscores its role in advancing green synthetic methodologies for pharmaceuticals and materials.

Properties

Chemical structure and nomenclature

DMTMM is the common abbreviation for 4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholin-4-ium , its full systematic IUPAC name. This compound belongs to the class of triazinylammonium salts, characterized by a central ring bearing methoxy substituents at the 4- and 6-positions. The is connected at the 2-position to the nitrogen of a 4-methylmorpholin-4-ium cation, forming a quaternary structure, with a anion serving as the .01137-6) The molecular of DMTMM is \ce{C10H17ClN4O3}, reflecting its composition of 10 carbon atoms, 17 atoms, 1 atom, 4 atoms, and 3 oxygen atoms. Its molecular weight is 276.72 g/mol, calculated based on this . The DMTMM originates from the structural descriptors in its IUPAC name, specifically highlighting the dimethoxy-1,3,5-triazin-2-yl and 4-methylmorpholinium components, along with the form.01137-6) This nomenclature was established in the compound's initial description, where it was denoted as DMT-MM to emphasize its role as a condensing agent, though the solid form is conventionally referred to as DMTMM.01137-6) The for this compound is 3945-69-5.

Physical and chemical properties

DMTMM appears as a to off-white crystalline solid. It exhibits high in polar solvents such as , , and (DMF), enabling its use in aqueous and alcoholic reaction media, while showing limited in non-polar solvents. The of DMTMM is approximately 114–120 °C. As a non-hygroscopic and shelf-stable compound, DMTMM maintains integrity when stored dry at -20 °C, though it undergoes gradual in moist environments over time. It remains stable in for several days at but shows signs of degradation under prolonged exposure to elevated temperatures in aqueous conditions. DMTMM is a , rendering it non-volatile and thermally up to its decomposition temperature.

History

Discovery and

DMTMM, or 4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium , was first reported in by Munetaka Kunishima and colleagues as a novel condensing agent for bond formation. The compound was synthesized quantitatively through the reaction of 2-chloro-4,6-dimethoxy-1,3,5-triazine (CDMT) with in (THF), yielding a , isolable that could be fully characterized by spectroscopic methods. This addressed the need for a more convenient alternative to activation methods using CDMT and tertiary amines, which often required careful control to avoid side reactions during carboxylic acid-amine couplings. The primary motivation behind DMTMM's creation stemmed from the demand for efficient, mild reagents in , where preserving is critical to avoid of chiral . Early evaluations demonstrated that DMTMM facilitates couplings in various solvents like THF, DMF, and under ambient conditions, producing amides in good yields without the harsh basicity associated with some prior activators. Subsequent studies confirmed its low propensity for racemization; for instance, a 2002 study showed that coupling Z(OMe)-Gly-L-Ala-OH with H-Phe-OBzl using DMTMM resulted in negligible epimerization in non-polar and moderately polar solvents, making it suitable for segment condensations in peptide assembly. By the mid-2000s, DMTMM's utility expanded beyond peptides to the modification of complex biomolecules, particularly . In 2007, researchers applied DMTMM to activate hyaluronic acid's carboxylic groups in aqueous media, enabling efficient amidation with amines to produce functionalized derivatives for biomedical applications, such as hydrogels and scaffolds. This adaptation highlighted DMTMM's versatility in water-compatible reactions, broadening its adoption in carbohydrate chemistry while maintaining the mild, non-racemizing profile established in its initial peptide-focused development.

Key publications and patents

The seminal publication introducing DMTMM (4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium chloride) was reported in 1999 by Kunishima et al. in Tetrahedron Letters, detailing its quantitative synthesis from 2-chloro-4,6-dimethoxy-1,3,5-triazine (CDMT) and (NMM) in , along with full characterization by NMR and spectroscopy. The paper demonstrated DMTMM's efficacy as a reagent for bond formation, achieving good yields under mild conditions. A follow-up study by the same research group in 1999, published in Synlett, expanded DMTMM's utility to ester synthesis, showing that carboxylic acids react with DMTMM in alcohols such as , , or isopropanol, in the presence of NMM, to afford the corresponding esters in 75-95% yields under mild conditions (, 1-24 hours), without the need for additional catalysts or dehydrating agents. This work highlighted DMTMM's versatility for forming both amides and esters via O-acylisourea-like active intermediates. A 2000 study in Synlett by Falchi et al. demonstrated DMTMM's effectiveness in solid-phase as a stable, non-hygroscopic alternative to , with yields and purity comparable to PyBOP for several oligopeptides. Insights into the broader applications and mechanistic aspects of DMTMM were provided in a comprehensive 2009 review by Valeur and in Chemical Society Reviews, which analyzed its role in activating carboxylic acids to form stable triazinyl active esters, enabling efficient nucleophilic attack by amines or alcohols while minimizing side reactions like or ; the review emphasized DMTMM's advantages in formation under aqueous or alcoholic conditions and its overall efficiency compared to other triazine-based reagents. Intellectual property related to DMTMM includes Japanese Patent JP2000226290A (filed 2000), which describes triazinium salts, including derivatives akin to DMTMM, as condensing agents for and couplings in . No significant international patents extending DMTMM's specific applications have been identified post-2000. DMTMM has been frequently cited in literature reviews on and sustainable coupling reagents, recognizing its eco-friendly profile due to low waste generation and compatibility with water-soluble substrates.

Synthesis

Preparation methods

DMTMM is typically prepared in the laboratory by the nucleophilic substitution reaction between 2-chloro-4,6-dimethoxy-1,3,5-triazine (CDMT) and N-methylmorpholine (NMM), where the tertiary amine of NMM attacks the triazine ring, displacing the chloride and forming the quaternary ammonium salt. This standard procedure is conducted in an aprotic solvent such as tetrahydrofuran (THF), dichloromethane (DCM), or acetonitrile at room temperature, often starting at 0 °C to control exothermicity before warming. The reaction is straightforward, requiring no additional base, as the chloride ion from the displaced chlorine in CDMT serves as the counterion in the product salt, and it proceeds efficiently without the need for inert atmosphere protection. The reaction equation is: \text{CDMT} + \text{NMM} \rightarrow \text{DMTMM} \cdot \text{Cl}^- Yields are high, typically reaching 80–95% after isolation of the precipitated product by and washing with a non-polar solvent like to remove unreacted materials. The process is scalable and produces DMTMM as a stable, white to off-white crystalline solid suitable for immediate use in reactions. Further purification, if required, involves recrystallization from hot or acetone, followed by cooling to afford analytically pure material with melting points around 116–120 °C. Variations include microwave-assisted heating, which can shorten the reaction time from 1–2 hours under conventional stirring to 5–10 minutes while maintaining comparable yields, particularly useful for generation during larger-scale preparations. This approach leverages the rapid heating to enhance the rate of quaternization without altering the overall procedure.

Precursors and reagents

The primary precursor for the synthesis of DMTMM (4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium ) is 2-chloro-4,6-dimethoxy-1,3,5-triazine (CDMT), which is typically prepared by the selective substitution of two chlorine atoms in with methoxy groups using in the presence of a base such as . CDMT serves as the electrophilic component that undergoes nucleophilic attack to form the key triazinyl structure of DMTMM. This precursor is commercially available from suppliers like and other chemical vendors, ensuring accessibility for laboratory-scale preparations. The nucleophilic reagent essential for DMTMM formation is (NMM), a tertiary amine that reacts with CDMT to generate the quaternary morpholinium salt, incorporating the ring into the final structure. NMM facilitates the quaternization by nucleophilic attack on the ring. Like CDMT, NMM is widely available from commercial sources such as , often in high purity suitable for . The reaction is commonly conducted in solvents like acetonitrile (MeCN) or dichloromethane (DCM), which provide optimal solubility for the precursors and help maintain reaction efficiency without interfering with the ionic intermediate formation. No catalysts or additives are typically required, as the reaction proceeds smoothly under mild conditions. DMTMM itself is commercially available as a stable, non-hygroscopic solid from suppliers including Sigma-Aldrich (product number 74104), allowing researchers to bypass in-house synthesis when preferred.

Applications

Amide synthesis

DMTMM, or 4-(4,6-Dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium , serves as an effective coupling reagent for bond formation by activating carboxylic acids toward nucleophilic attack by amines. This triazinium salt enables the direct of carboxylic acids with primary or secondary amines under mild conditions, avoiding the need for prior conversion to acid or other reactive intermediates. The reagent is particularly valued in for its compatibility with sensitive functional groups and its ability to operate in protic solvents, including water.00809-1) The general procedure involves combining the carboxylic acid and amine (typically in a 1:1 molar ratio) with 1–1.2 equivalents of DMTMM in a solvent such as dimethylformamide (DMF) or aqueous buffer at neutral pH and room temperature, with reaction times ranging from 1 to 24 hours. Yields are generally high, often 80–99%, and the process exhibits minimal racemization (less than 1% epimerization) when applied to chiral amino acids, making it suitable for stereosensitive applications. Byproducts include N-methylmorpholine (NMM) and 4,6-dimethoxy-1,3,5-triazin-2-ol (DMTOH), both of which are water-soluble and easily removable by extraction or precipitation, enhancing purification efficiency. The reaction can be represented as: \ce{R-COOH + R'-NH2 + DMTMM -> R-CO-NH-R' + NMM \cdot HCl + DMTOH} 00809-1) Representative examples illustrate DMTMM's versatility. In peptide synthesis, it facilitates the coupling of protected amino acids, such as Boc-Ala-OH with glycine methyl ester (Gly-OMe), to yield the dipeptide Boc-Ala-Gly-OMe in excellent yield with negligible racemization. The reagent is also effective for challenging substrates, including sterically hindered amines and biopolymers; for instance, hyaluronic acid can be amidated with benzylamine in phosphate buffer at pH 6 and 70°C, achieving a degree of substitution up to 40%. DMTMM's scope extends to both aliphatic and aromatic carboxylic acids and amines, performing well in aqueous media for green chemistry applications.

Ester and other carboxylic acid derivatives

DMTMM serves as an effective coupling reagent for the esterification of s with s, proceeding through the formation of a reactive O-acylisourea-like that is subsequently attacked by the . The general procedure involves treating the with 1.1 equivalents of DMTMM and (NMM) in the presence of the , often using the itself as the solvent for simple cases or (DCM) or for more complex or sensitive substrates. This approach delivers yields typically in the range of 70–90% for primary alkyl and benzylic s, offering advantages over traditional methods like esterification by avoiding harsh acidic conditions and enabling compatibility with protic environments. Representative examples illustrate the versatility of this method. For instance, the reaction of with in the presence of DMTMM and NMM proceeded at to afford in 92% isolated yield after 5 hours. Similarly, acetic acid and under analogous conditions yielded in 85% yield. The reagent has also been applied to polyol substrates, such as in the activation of carboxylic groups on for ester linkage with , resulting in cross-linked films with enhanced mechanical strength and flexibility suitable for material applications analogous to structures. Beyond simple esters, DMTMM enables the preparation of other derivatives, including thioesters via reaction with thiols under similar activation conditions. Its utility extends to depsipeptide synthesis, where it facilitates ester bond formation in peptide contexts. A notable application is the of the cyclic depsipeptide , in which DMTMM tetrafluoroborate (DMTMM·BF₄) mediated the key macrolactonization of a linear precursor with a D-threonine residue, closing the 13-membered ring and delivering the natural product in 3.3% overall yield over 24 steps. This highlights DMTMM's role in constructing complex ester linkages in bioactive molecules, though its efficiency diminishes for sterically hindered alcohols relative to amide couplings due to reduced nucleophilic accessibility.

Reaction mechanism

Activation of carboxylic acids

The activation of carboxylic acids by DMTMM involves a mechanism, wherein the anion derived from the attacks the electrophilic carbon at the 2-position of the triazinium ring in DMTMM, displacing neutral (NMM), which is protonated to N-methylmorpholinium chloride using the acidic proton from the . This step generates the reactive O-(4,6-dimethoxy-1,3,5-triazin-2-yl) , commonly referred to as the active , which serves as a highly electrophilic for subsequent nucleophilic acyl substitutions. The transformation can be summarized by the following equation: \ce{RCO2H + DMTMM -> RCO2-C3N3(OMe)2 + NMM \cdot HCl} where the active ester is depicted with the 4,6-dimethoxy-1,3,5-triazin-2-yl moiety attached to the carboxylate oxygen, DMTMM represents the triazinium salt, and NMM·HCl is N-methylmorpholinium chloride. This activation step proceeds efficiently under neutral to mildly basic conditions (pH 6–8), often in protic solvents such as water or alcohols, and is complete within minutes at ambient temperature, enabling rapid preparation of the intermediate without the need for stringent anhydrous conditions.

Nucleophilic attack and byproduct formation

In the nucleophilic attack step of the DMTMM-mediated , the or adds to the carbonyl carbon of the active O-acyloxytriazinyl intermediate, displacing the 4,6-dimethoxy-1,3,5-triazin-2-olate and forming the corresponding or product. This step follows the initial activation of the and proceeds efficiently due to the enhanced electrophilicity of the carbonyl. The byproducts of this displacement are (NMM), which acts as a recyclable base, and 4,6-dimethoxy-1,3,5-triazin-2-ol, a water-soluble that is non-toxic and readily separable. These species arise from the collapse of the intermediate, with NMM released as the neutral base (often as its depending on reaction conditions) and the triazinolate protonated to the alcohol form. This process is depicted by the general equation: \ce{RC(O)-O-(C3N3(OMe)2) + NuH -> RC(O)Nu + HO-(C3N3(OMe)2)} where \ce{RC(O)} represents the , \ce{NuH} is the (e.g., or ), and \ce{(C3N3(OMe)2)} denotes the 4,6-dimethoxy-1,3,5-triazin-2-yl moiety. Kinetically, the nucleophilic attack exhibits second-order dependence on the concentrations of the active ester and , serving as a key rate-determining phase in the overall . In aqueous media, aminolysis is strongly favored over , with the rate of attack on the estimated to be approximately $2 \times 10^4 times faster than competing solvolysis processes, enabling high selectivity for formation even in protic solvents. The non-toxic, water-soluble nature of the byproducts allows for their straightforward removal via , minimizing waste and enhancing the environmental profile of DMTMM couplings.

Safety and handling

Health hazards

DMTMM is classified as (H302) and causes severe skin burns and eye damage (H314) under the Globally Harmonized System (GHS) of classification and labeling of chemicals, indicating potential via oral exposure and corrosive effects on and eyes. It is also a skin sensitizer classified under GHS Category 1A (H317: May cause an allergic skin reaction), based on positive results from dermal sensitization studies using the local assay (LLNA) according to Test Guideline 429, where it demonstrated strong potential with an EC3 value below 1%. The primary routes of exposure to DMTMM include , direct , and of dust or vapors generated during handling. to DMTMM can cause severe burns to and eyes, as well as to the , with symptoms including redness, , , blistering, and potential permanent damage from short-term . Repeated or prolonged may lead to allergic due to its sensitizing properties. The acute oral LD50 for DMTMM in rats is 1,091 mg/kg, classifying it as having low acute toxicity but still warranting caution for ingestion. No chronic toxicity studies have been documented in available safety assessments. Limited ecotoxicity data are available for DMTMM, but precautionary measures in safety guidelines recommend avoiding release into waterways due to potential harm to aquatic organisms.

Storage and precautions

DMTMM is moisture-sensitive and must be stored in a tightly closed, airtight in a environment under an atmosphere at -20 °C to prevent and maintain stability. Under these conditions, the compound has a typical shelf life of 1 year from the date of shipment, as per supplier warranty, though specific stability data may vary by batch. Safe handling requires the use of , including protective gloves (such as ), tightly fitting safety goggles, a lab coat or flame-retardant antistatic protective clothing, and a with P2 filter if is generated. All operations should be performed in a well-ventilated to avoid of or vapors, and contact with ignition sources, open flames, or hot surfaces must be avoided due to its combustible nature. During transfer, use a or similar tool to minimize formation and exposure to atmospheric moisture. In the event of spills, immediately cover nearby drains to prevent entry into waterways, collect the spilled material using methods that avoid generating dust, and clean the affected area thoroughly while ensuring adequate . Dispose of DMTMM and any contaminated materials as in accordance with local, national, and international regulations, typically through or at an approved waste disposal facility after appropriate if required by . For first aid, if skin contact occurs, remove contaminated clothing and rinse the affected area immediately with plenty of and , followed by seeking attention if irritation persists. In cases of eye contact, flush eyes with for at least 15 minutes while holding eyelids open and remove contact lenses if present, then consult an ophthalmologist immediately. If ingested, do not induce vomiting; have the person drink up to two glasses of and seek urgent help. For , move the individual to fresh air and call a if symptoms develop.

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    ### Summary of Handling and Storage, Personal Protection, Accidental Release Measures, Disposal Considerations, First Aid Measures