ライフサイエンスコーパス: thermolytic

1 ctionalizing the poly(G) track of D ODN with thermolytic 2-(N-formyl-N-methyl)aminoethyl (fma) phosph

2 is of oligonucleoside phosphorothioates, the thermolytic 2-[N-methyl-N-(2-pyridyl)]aminoethyl thiopho

3 nyl)formamidinate) have been investigated by thermolytic and photolytic experiments to investigate th

4 droxyl protection of deoxyribonucleosides as thermolytic carbonates.

5 tudied immunomodulatory CpG ODN 1555 through thermolytic cleavage of the 2-(N-formyl-N-methyl)aminoet

6 it can be readily removed, as needed, under thermolytic conditions at neutral pH.

7 Depending on the thermolytic conditions, dicobalthexacarbonyl-complexed e

8 aration of unsaturated compounds under mild, thermolytic conditions.

9 mma-lactones efficiently under photolytic or thermolytic conditions.

10 axanthone A was achieved using solvent-free, thermolytic conditions.

11 on through the formation of a N-N bond under thermolytic conditions.

12 Several thermolytic CpG-containing DNA oligonucleotides analogou

13 The thermolytic decomposition of Cs(9)MO(4) is a multistep p

14 We exploit the thermolytic decomposition of Mo(CO)(6) in the presence o

15 Complete thermolytic deprotection of carbonates 7, 8, 13, and 14

16 Thermolytic deprotection of these carbonates is preferab

17 opeptides were isolated in high yield from a thermolytic digest of porcine fibrinogen.

18 continuously release small amounts of HCl by thermolytic elimination.

19 Thermolytic extrusion of SO(2) from polymer-bound 3-(phe

20 Additionally, thermolytic groups are attractive in the context of engi

21 Thermolytic groups may serve as alternatives to the conv

22 Thermolytic groups structurally related to well-studied

23 y, and 3 required an 11-step sequence with a thermolytic intramolecular inverse-demand Diels-Alder re

24 t of the P-domain was also identified in the thermolytic mixture.

25 tion of surface organometallic chemistry and thermolytic molecular precursor approach was used to pre

26 The scope of thermolytic, N-Boc deprotection was studied on 26 compou

27 irus infection, and thus supports the use of thermolytic oligonucleotides as prodrugs in the effectiv

28 ature (LCST) type of phase behavior as novel thermolytic osmotic agents.

29 ermolysis of 1, and kinetics studies of this thermolytic pathway indicate that the reductive eliminat

30 ntial application of pyridine derivatives as thermolytic phosphate/thiophosphate protecting groups ha

31 cid as both a synthetic building block and a thermolytic precursor to dialkyl ketenes.

32 its use as a single source precursor in the thermolytic production of luminescent rare earth metal d

33 r most of the ethanol had been depleted when thermolytic S(2)O(8)(2-) decomposition resulted in produ

34 Most of the existing studies have focused on thermolytic salt systems.

35 gradients using synthetic solutions, such as thermolytic salts.

36 low application was extended further for the thermolytic skeletal rearrangement of 3-azide-2-oxindole

37 tem utilized nanothermal analysis probes for thermolytic surface sampling followed by atmospheric pre