波谱学杂志
波譜學雜誌
파보학잡지
Chinese Journal of Magnetic Resonance
2015年
4期
563-573
,共11页
胡浩%韦芝良%林良杰%孙惠军%林雁勤%陈忠
鬍浩%韋芝良%林良傑%孫惠軍%林雁勤%陳忠
호호%위지량%림량걸%손혜군%림안근%진충
核磁共振(NMR)%选择编码%二维核磁共振谱%空间编码%超快速
覈磁共振(NMR)%選擇編碼%二維覈磁共振譜%空間編碼%超快速
핵자공진(NMR)%선택편마%이유핵자공진보%공간편마%초쾌속
nuclear magnetic resonance (NMR)%selective encoding%two-dimensional NMR spectrum%spatial encoding%ultrafast
核磁共振(NMR)波谱技术是当今最有力的谱学工具之一,在化学、生物和医药等众多领域获得重要而广泛的应用。基于时空编码的快速采样方法自2002年Frydman小组提出后,大大增强了高维磁共振波谱的采样效率。在某一些应用体系中,存在若干个强度远超于其他谱峰的情况,很容易由于动态增益不足而检测不到某些较弱的谱峰,而往往这些较弱的谱峰包含着感兴趣的信息。且在实际的化学生物应用中,存在选择性感兴趣检测的情况,即只需要选择性地观察若干个具有标记作用的谱峰。由于时空编码技术借助于高速切换的双极性梯度来完成解码,因而无法选择性地检测若干个非连续的频点。为解决以上两个问题,该文提出一种选择编码的时空编码方法,即在序列中施加选择性脉冲,选择性破坏某些谱峰的编码过程,使之不能在解码期解码,从而简化谱图,实现选择性压制或者非连续频点的感兴趣检测。如果把选择性反转脉冲换为硬反转脉冲加选择性反转脉冲,则最终的谱图中只出现被选择性脉冲选中的谱峰。理论分析及相关的实验验证了这种方法的可行性和有效性。
覈磁共振(NMR)波譜技術是噹今最有力的譜學工具之一,在化學、生物和醫藥等衆多領域穫得重要而廣汎的應用。基于時空編碼的快速採樣方法自2002年Frydman小組提齣後,大大增彊瞭高維磁共振波譜的採樣效率。在某一些應用體繫中,存在若榦箇彊度遠超于其他譜峰的情況,很容易由于動態增益不足而檢測不到某些較弱的譜峰,而往往這些較弱的譜峰包含著感興趣的信息。且在實際的化學生物應用中,存在選擇性感興趣檢測的情況,即隻需要選擇性地觀察若榦箇具有標記作用的譜峰。由于時空編碼技術藉助于高速切換的雙極性梯度來完成解碼,因而無法選擇性地檢測若榦箇非連續的頻點。為解決以上兩箇問題,該文提齣一種選擇編碼的時空編碼方法,即在序列中施加選擇性脈遲,選擇性破壞某些譜峰的編碼過程,使之不能在解碼期解碼,從而簡化譜圖,實現選擇性壓製或者非連續頻點的感興趣檢測。如果把選擇性反轉脈遲換為硬反轉脈遲加選擇性反轉脈遲,則最終的譜圖中隻齣現被選擇性脈遲選中的譜峰。理論分析及相關的實驗驗證瞭這種方法的可行性和有效性。
핵자공진(NMR)파보기술시당금최유력적보학공구지일,재화학、생물화의약등음다영역획득중요이엄범적응용。기우시공편마적쾌속채양방법자2002년Frydman소조제출후,대대증강료고유자공진파보적채양효솔。재모일사응용체계중,존재약간개강도원초우기타보봉적정황,흔용역유우동태증익불족이검측불도모사교약적보봉,이왕왕저사교약적보봉포함착감흥취적신식。차재실제적화학생물응용중,존재선택성감흥취검측적정황,즉지수요선택성지관찰약간개구유표기작용적보봉。유우시공편마기술차조우고속절환적쌍겁성제도래완성해마,인이무법선택성지검측약간개비련속적빈점。위해결이상량개문제,해문제출일충선택편마적시공편마방법,즉재서렬중시가선택성맥충,선택성파배모사보봉적편마과정,사지불능재해마기해마,종이간화보도,실현선택성압제혹자비련속빈점적감흥취검측。여과파선택성반전맥충환위경반전맥충가선택성반전맥충,칙최종적보도중지출현피선택성맥충선중적보봉。이론분석급상관적실험험증료저충방법적가행성화유효성。
Nuclear Magnetic Resonance (NMR) is one of the most powerful analytical tools nowadays, with wide applications in the fields of chemistry, biology and medicine. The spatial encoding ultrafast method proposed by Frydmanet al. in 2002 greatly enhanced the sampling efficiency of multi-dimensional NMR spectroscopy. One problem with the Frydman’s method is that it is difficult to selectively detect multiple resonances at non-continuous discrete frequencies, due to the fast-switching bipolar gradients that are required for spatial encoding. In this study, we proposed a novel selective spatial encoding ultrafast method, aiming to solve two problems often encountered when utilizing the Frydman’s method in practical chemical and biological applications. The first problem is to detect weak signals in the presence of strong signals with limited dynamic range; and the second problem is to detect the signals of interests (e.g., peaks from labeled nuclei) exclusively with the rest of resonances in the background unexcited. The proposed method utilized a selective pulse to destroy the encoding process selectively, such that selective suppression of strong peaks or excitation of non-continuous discrete frequency points of interest could be achieved. We also showed that only the spectral peak selected by the selective pulse would remain if the selective inverse pulse was replaced by a hard inverse pulse. The feasibility and validity of this method were demonstrated by both theoretical analyses and experiments.
