SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2593705730> ?p ?o ?g. }

Showing items 1 to 100 of ±150 with 100 items per page.

W2593705730 endingPage "831" @default.
W2593705730 startingPage "823" @default.
W2593705730 abstract "DNA is well-known as bearer of the genetic code. Since its structure elucidation nearly seven decades ago by Watson, Crick, Wilkins, and Franklin, much has been learned about its detailed structure, function, and genetic coding. The development of automated solid-phase synthesis, and with it the availability of synthetic DNA with any desired sequence in lengths of up to hundreds of bases in the best case, has contributed much to the advancement of the field of DNA research. In addition, classic organic synthesis has allowed introduction of a very large number of modifications in the DNA in a sequence specific manner, which have initially been targeted at altering the biological function of DNA. However, in recent years DNA has become a very attractive scaffold in supramolecular chemistry, where DNA is taken out of its biological role and serves as both stick and glue molecule to assemble novel functional structures with nanometer precision. The attachment of functionalities to DNA has led to the creation of supramolecular systems with applications in light harvesting, energy and electron transfer, sensing, and catalysis. Functional DNA is clearly having a significant impact in the field of bioinspired nanosystems. Of particular interest is the use of porphyrins in supramolecular chemistry and bionanotechnology, because they are excellent functional groups due to their electronic properties that can be tailored through chemical modifications of the aromatic core or through insertion of almost any metal of the periodic table into the central cavity. The porphyrins can be attached either to the nucleobase, to the phosphate group, or to the ribose moiety. Additionally, noncovalent templating through Watson-Crick base pairing forms an alternative and attractive approach. With this, the combination of two seemingly simple molecules gives rise to a highly complex system with unprecedented possibilities for modulation of function, and with it applications, particularly when combined with other functional groups. Here, an overview is given on the developments of using porphyrin modified DNA for the construction of functional assemblies. Strategies for the synthesis and characterization are presented alongside selected applications where the porphyrin modification has proven to be particularly useful and superior to other modifiers but also has revealed its limitations. We also discuss implications on properties and behavior of the porphyrin-DNA, where similar issues could arise when using other hydrophobic and bulky substituents on DNA. This includes particularly problems regarding synthesis of the building blocks, DNA synthesis, yields, solubility, and intermolecular interactions." @default.
W2593705730 created "2017-03-16" @default.
W2593705730 creator A5027548381 @default.
W2593705730 date "2017-03-08" @default.
W2593705730 modified "2023-10-16" @default.
W2593705730 title "Nanoarchitectonics with Porphyrin Functionalized DNA" @default.
W2593705730 cites W1755902921 @default.
W2593705730 cites W1791746369 @default.
W2593705730 cites W1793582810 @default.
W2593705730 cites W1883683178 @default.
W2593705730 cites W1967952840 @default.
W2593705730 cites W1968842548 @default.
W2593705730 cites W1970710366 @default.
W2593705730 cites W1974205571 @default.
W2593705730 cites W1977457929 @default.
W2593705730 cites W1977685010 @default.
W2593705730 cites W1980888135 @default.
W2593705730 cites W1984985732 @default.
W2593705730 cites W1993783539 @default.
W2593705730 cites W2001363020 @default.
W2593705730 cites W2003830867 @default.
W2593705730 cites W2005240531 @default.
W2593705730 cites W2009050461 @default.
W2593705730 cites W2015927837 @default.
W2593705730 cites W2020151064 @default.
W2593705730 cites W2021255847 @default.
W2593705730 cites W2023867834 @default.
W2593705730 cites W2025149216 @default.
W2593705730 cites W2025366987 @default.
W2593705730 cites W2025865701 @default.
W2593705730 cites W2027350263 @default.
W2593705730 cites W2029009897 @default.
W2593705730 cites W2031139017 @default.
W2593705730 cites W2040778984 @default.
W2593705730 cites W2043836941 @default.
W2593705730 cites W2047333772 @default.
W2593705730 cites W2053984194 @default.
W2593705730 cites W2059810061 @default.
W2593705730 cites W2061985383 @default.
W2593705730 cites W2063190310 @default.
W2593705730 cites W2064553787 @default.
W2593705730 cites W2070305125 @default.
W2593705730 cites W2072959862 @default.
W2593705730 cites W2080488405 @default.
W2593705730 cites W2090915778 @default.
W2593705730 cites W2092702252 @default.
W2593705730 cites W2092899663 @default.
W2593705730 cites W2099147459 @default.
W2593705730 cites W2100478802 @default.
W2593705730 cites W2103028853 @default.
W2593705730 cites W2110460459 @default.
W2593705730 cites W2115162870 @default.
W2593705730 cites W2117208578 @default.
W2593705730 cites W2126466006 @default.
W2593705730 cites W2129561718 @default.
W2593705730 cites W2130796369 @default.
W2593705730 cites W2131935889 @default.
W2593705730 cites W2133955727 @default.
W2593705730 cites W2136462049 @default.
W2593705730 cites W2156363739 @default.
W2593705730 cites W2168337196 @default.
W2593705730 cites W2170700475 @default.
W2593705730 cites W2287470078 @default.
W2593705730 cites W2312572229 @default.
W2593705730 cites W2322466256 @default.
W2593705730 cites W2408793797 @default.
W2593705730 cites W2416975419 @default.
W2593705730 cites W2466119970 @default.
W2593705730 cites W2473823884 @default.
W2593705730 cites W2520457390 @default.
W2593705730 cites W2616798345 @default.
W2593705730 cites W4255478734 @default.
W2593705730 doi "https://doi.org/10.1021/acs.accounts.6b00583" @default.
W2593705730 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/5397883" @default.
W2593705730 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/28272871" @default.
W2593705730 hasPublicationYear "2017" @default.
W2593705730 type Work @default.
W2593705730 sameAs 2593705730 @default.
W2593705730 citedByCount "90" @default.
W2593705730 countsByYear W25937057302017 @default.
W2593705730 countsByYear W25937057302018 @default.
W2593705730 countsByYear W25937057302019 @default.
W2593705730 countsByYear W25937057302020 @default.
W2593705730 countsByYear W25937057302021 @default.
W2593705730 countsByYear W25937057302022 @default.
W2593705730 countsByYear W25937057302023 @default.
W2593705730 crossrefType "journal-article" @default.
W2593705730 hasAuthorship W2593705730A5027548381 @default.
W2593705730 hasBestOaLocation W25937057301 @default.
W2593705730 hasConcept C155672457 @default.
W2593705730 hasConcept C171250308 @default.
W2593705730 hasConcept C178790620 @default.
W2593705730 hasConcept C185581394 @default.
W2593705730 hasConcept C185592680 @default.
W2593705730 hasConcept C192562407 @default.
W2593705730 hasConcept C21951064 @default.
W2593705730 hasConcept C26926545 @default.
W2593705730 hasConcept C2779480358 @default.