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PMCC polymer

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PMCC structure

Poly (tetrahydropyran-2-yl N-(2 methacryloxyethyl) carbamate)-b-(methyl 4-(3-methacryloyloxypropoxy) cinnamate) (PMCC) is a synthetic polymer with thermally active groups, which upon heating, decomposes and exposes primary amines, providing a basis for surface modification. The structure of PMCC is based on a PMMA backbone with different functional groups on its sidechain. It is soluble in cyclohexanone or chloroform and has been used to create bone tissue replicas and to study protein immobilization in biological sciences.[1][2][3]

Structure and synthesis

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PMCC is a cinnamate-carbamate copolymer synthesized by a mixture of methacrylate monomers, a cinnamate monomer ("A", methyl 4-(3-methacryloyloxypropoxy) cinnamate) and a carbamate monomer ("B", tetrahydropyran-2-yl N-(2-methacryloxyethyl) carbamate). Polymerization of the two synthesized monomers is carried out through a radical polymerization using azobisisobutrylnitrile (ABIN) in tetrahydropyran (THP) with the temperature of 60 °C.

Synthesis of the cinnamate-carbamate copolymer

Chemical properties

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Pyrolysis

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PMCC possesses two distinct decomposition/deprotection temperatures (Td). One starts around 150 °C and accounts for 80% of the mass loss, and the second starts around 210 °C that accounts for the last 20%. When decomposition temperature is 150-180 °C, the carbamate monomer "B" of PMCC tends to decompose to carbon dioxide, 3,4-Dihydro-2H-pyran and polymer with primary amine groups.

Pyrolysis of PMCC

Applications

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PMCC is used mainly as a functional layer for grafting chemicals on substrates in nanoscale chemical patterning together with thermochemical nanolithography (tc-SPL) which involves the use of a heated nanoscale tip to thermally deprotect amine groups on the PMCC polymer surface. Patterning resolution with tc-SPL on PMCC as small as sub-10 nm, with depths as small as sub-2nm and at speeds up to millimeters per second have been reported.[3][4] After the deprotection of the PMCC, the chemical function of the pattern is achieved by attaching various nano-objects to exposed amine groups.[5]

Liu et al. demonstrated the ability to create complex patterns with different functionalities by using PMCC and tc-SPL technology, including the electrostatic immobilization of negatively charged sulfonated enzymes at positively charged amine patterns.[6] These capabilities have significant implications for nanobiotechnology, as they could be used for the development of protein chips, and in studies of nanoelectronics fabrications.

References

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  1. ^ Wang, Debin; Kodali, Vamsi K.; Underwood II, William D.; Jarvholm, Jonas E.; Okada, Takashi; Jones, Simon C.; Rumi, Mariacristina; Dai, Zhenting; King, William P.; Marder, Seth R.; Curtis, Jennifer E.; Riedo, Elisa (2009-12-03). "Nanolithography: Thermochemical Nanolithography of Multifunctional Nanotemplates for Assembling Nano-Objects (Adv. Funct. Mater. 23/2009)". Advanced Functional Materials. 19 (23). doi:10.1002/adfm.200990104. ISSN 1616-301X.
  2. ^ Zanut, Alessandra; Li, Rui; Deng, Ru; Liu, Xiangyu; Rejhon, Martin; Chen, Weiqiang; Weck, Marcus; de Peppo, Giuseppe Maria; Riedo, Elisa (2023-01-13). "A Polymer Canvas with the Stiffness of the Bone Matrix to Study and Control Mesenchymal Stem Cell Response". Advanced Healthcare Materials. 12 (10): e2201503. doi:10.1002/adhm.202201503. ISSN 2192-2640. OSTI 2420876. PMID 36565136.
  3. ^ a b Liu, Xiangyu; Zanut, Alessandra; Sladkova-Faure, Martina; Xie, Liyuan; Weck, Marcus; Zheng, Xiaorui; Riedo, Elisa; de Peppo, Giuseppe Maria (May 2021). "Cost and Time Effective Lithography of Reusable Millimeter Size Bone Tissue Replicas With Sub-15 nm Feature Size on A Biocompatible Polymer". Advanced Functional Materials. 31 (19). doi:10.1002/adfm.202008662. ISSN 1616-301X.
  4. ^ Albisetti, E; Carroll, K M; Lu, X; Curtis, J E; Petti, D; Bertacco, R; Riedo, E (2016-06-27). "Thermochemical scanning probe lithography of protein gradients at the nanoscale". Nanotechnology. 27 (31): 315302. Bibcode:2016Nanot..27E5302A. doi:10.1088/0957-4484/27/31/315302. hdl:11311/1004178. ISSN 0957-4484. PMID 27344982.
  5. ^ Carroll, Keith M.; Giordano, Anthony J.; Wang, Debin; Kodali, Vamsi K.; Scrimgeour, Jan; King, William P.; Marder, Seth R.; Riedo, Elisa; Curtis, Jennifer E. (2013-06-25). "Fabricating Nanoscale Chemical Gradients with ThermoChemical NanoLithography". Langmuir. 29 (27): 8675–8682. doi:10.1021/la400996w. ISSN 0743-7463. PMID 23751047.
  6. ^ Liu, Xiangyu; Kumar, Mohit; Calo, Annalisa; Albisetti, Edoardo; Zheng, Xiaorui; Manning, Kylie B.; Elacqua, Elizabeth; Weck, Marcus; Ulijn, Rein V.; Riedo, Elisa (2019-10-14). "Sub-10 nm Resolution Patterning of Pockets for Enzyme Immobilization with Independent Density and Quasi-3D Topography Control". ACS Applied Materials & Interfaces. 11 (44): 41780–41790. doi:10.1021/acsami.9b11844. ISSN 1944-8244. PMID 31609566.