A complete set of novel 2D correlation NMR experiments based on heteronuclear J-cross polarization

A suite of multiple-purpose sensitivity-enhanced 2D correlation NMR experiments based on heteronuclear J-cross polarization (HCP) techniques are introduced for isotropic liquid samples. Several pulse sequences using an adaptable heteronuclear TOCSY mixing building block are proposed for different types of effective coherence-order-selective (COS) heteronuclear coherence-transfer mechanisms. They are based on the anisotropic behaviour of the involved HCP process that is easily described and analysed in terms of cartesian product-operator formalism. A number of different versions are given for in-phase to in-phase (II-COS: S (-) \\ to I (-)), in-phase to anti-phase (IA-COS: S (-) \\ to 2 I (-) S (z)), in-phase to spin-state-selective (IS(3)-COS: S (-) \\ to 2 I (-) S (alpha /beta)), anti-phase to in-phase (AI-COS: 2 I (z) S (-) \\ to I (-)), anti-phase to anti-phase (AA-COS: 2 I (z) S (-) \\ to 2 I (-) S (z)), anti-phase to spin-state-selective (AS(3)-COS: 2 I (z) S (-) \\ to 2 I (-) S (alpha /beta)) and spin-state-selective to spin-state-selective (S(3)S(3)-COS: 2 I (alpha /beta) S (-) \\ to 2 I (-) S (alpha /beta )) coherence transfers. The combination of the echo/anti-echo approach, heteronuclear gradient echoes and the preservation of equivalent pathways (PEP) methodology affords a general approach to obtain sensitivity-enhanced pure-absorption 2D spectra that can be used as interesting alternatives to conventional pulse-interrupted free-precession INEPT-based pulse schemes, such as HSQC-type and TROSY-type experiments.