ライフサイエンスコーパス: Synthetic Receptor

1 pt helical conformations when bound within a synthetic receptor.

2 get molecules, exceeding the values of known synthetic receptors.

3 the lines of distinction between natural and synthetic receptors.

4 xanthine were investigated as guests for the synthetic receptors.

5 preparing polymer scaffolds that function as synthetic receptors.

6 r binding of alkanes in water to hydrophobic synthetic receptors.

7 ology but has been difficult to achieve with synthetic receptors.

8 We have reported that synthetic receptor 1 recognizes inositol trisphosphate (

9 Jurkat lymphocytes treated with the synthetic receptor (10 microM) for 1 h displayed approxi

10 Although, the synthetic receptor alone has higher selectivity for citr

11 Here, an unprecedented synthetic receptor, an aryl-substituted calix[4]pyrrole

12 Biological recognition probes such as synthetic receptor and aptamer is one of the candidate r

13 rochemical sensors plus recent advances with synthetic receptors and molecularly imprinted polymers.

14 Furthermore, synthetic receptor antagonists that specifically block C

15 Therefore, both selective and nonselective synthetic receptors are finding uses in analytical appli

16 n previous decades upon the study and use of synthetic receptors as a means of mimicking natural rece

17 Complexations of natural products with synthetic receptors as well as the use of natural produc

18 A series of synthetic receptors capable of binding to the calmodulin

19 are under thermodynamic control, leading to synthetic receptors, catalytic systems, and complex self

20 Natural retinoids and synthetic receptor class- or subtype-selective retinoid

21 These synthetic receptors comprise N-alkyl derivatives of 3bet

22 pproach integrates for the first time hybrid synthetic receptors comprising of highly selective aptam

23 Synthetic receptors could aid dissolution provided they

24 These synthetic receptors could offer a new and promising imag

25 escribes the binding of human insulin by the synthetic receptor cucurbit[7]uril (Q7) in vitro.

26 lanine derivatives and their peptides by the synthetic receptor cucurbit[7]uril (Q7).

27 gnition of the tripeptide Tyr-Leu-Ala by the synthetic receptor cucurbit[8]uril (Q8) in aqueous buffe

28 Here we report a synthetic receptor designed to form threaded complexes (

29 urface imprinted by insulin, which acts as a synthetic receptor for reversible analyte inclusion.

30 power and utility of a differential array of synthetic receptors for identification and discriminatio

31 on some recent aspects in the development of synthetic receptors for selective sulfate anion recognit

32 he potential use of phosphonate cavitands as synthetic receptors for the detection of epigenetic modi

33 This synthetic receptor fulfils a role reminiscent of a catal

34 A new design criterion for aqueous synthetic receptors has therefore emerged, which is the

35 Synthetic receptors have a wide range of potential appli

36 Although many synthetic receptors have been shown to yield exquisite s

37 This synthetic receptor inserts into cellular plasma membrane

38 A synthetic receptor is described with the appropriate sha

39 e of the most promising areas for the use of synthetic receptors is in the arena of differential sens

40 Recently, the demand for synthetic receptors is rapidly increasing within the ana

41 Synthetic receptor-ligand systems that remove the native

42 used to combine the beneficial properties of synthetic receptor ligands with antibody fragments to de

43 Our synthetic receptor-mediated affinity labeling approach b

44 We report a synthetic receptor mimic that transmits structural infor

45 ike electrochemiluminescent sensor (based on synthetic receptors-molecularly imprinted polymers), as

46 A water-soluble synthetic receptor molecule is capable of selective, con

47 lled an average of approximately 6.2 x 10(5) synthetic receptor molecules per cell surface.

48 The reactions inside this synthetic receptor occurred in a catalytic and regiosele

49 Because of their relative simplicity, synthetic receptors often lack the selectivity observed

50 cyclodextrin derivatives were synthesized as synthetic receptors (or host molecules) of rocuronium br

51 opment of a unique labeling method wherein a synthetic receptor probe for trimethyl lysine (Kme3), CX

52 natural all-trans retinoic acid and to many synthetic receptor-selective retinoids.

53 y reports the design and evaluation of a new synthetic receptor sensor based on the amalgamation of b

54 Our synthetic receptor showed good affinities, not unlike th

55 We first review the development of synthetic receptors, switches, and circuits to control t

56 In a similar vein, we describe here a synthetic receptor that allows direct observation of lab

57 e we describe the design and evaluation of a synthetic receptor that binds to the exterior surface of

58 para-phenylene-based cyclophane results in a synthetic receptor that is ~2 nm long and adopts a box-l

59 Synthetic receptors that are likewise capable of multi-s

60 y of signal receptors to design and engineer synthetic receptors that comprise two PAS sensor domains

61 g has been assessed by preparing a family of synthetic receptors that incorporate the aromatic side c

62 Chimeric antigen receptors (CARs) are synthetic receptors that mediate antigen recognition, T

63 ng complex functions, it is useful to design synthetic receptors that mimic their biological counterp

64 Chimeric antigen receptors (CARs) are synthetic receptors that redirect and reprogram T cells

65 These CAR T cells are engineered to express synthetic receptors that redirect polyclonal T cells to

66 CARs are synthetic receptors that reprogram immune cells for ther

67 eric antigen receptors (CARs) are a class of synthetic receptors that reprogram lymphocyte specificit

68 The association of synthetic receptors to target guests often proceeds thro

69 ent of a holographic sensor, which employs a synthetic receptor, to enable the selective and continuo

70 a number of indolocarbazole- and urea-based synthetic receptors toward acetate ion in DMSO-d6/H2O (9

71 The MIP synthetic receptor was deposited by potentiodynamic elec

72 The extracellular domain of one of these synthetic receptors was derived from a single-chain anti

73 The hybrid synthetic receptors were constructed by immobilizing an

74 The hybrid synthetic receptors were subsequently used in an extende

75 ecules (see scheme; red) in a membrane-bound synthetic receptor (yellow).