紫杉醇治疗小鼠S180肉瘤的体内31P MRS研究

为了研究紫杉醇治疗小鼠S180肉瘤的³¹P MRS参数的变化及这些参数的变化是否早于常规观察的瘤体积的变化.方法:利用表面线圈³¹P NMR方法,研究小鼠皮下接种的S180肉瘤.结果:用药48h后给药组的PCr/Pi、β-NTP/Pi、PME/β-NTP比值与对照组有显著性差别(P<0.05),而肿瘤体积在给药组和对照组之间无显著性差别,³¹P MRS参数的变化早于瘤体积变化.结论:小鼠S180肉瘤³¹P MRS不仅可以给出定量的结果,而且可以较早地显示出治疗的效果.     

小鼠大脑急性缺血过程中31P NMR研究

利用³¹P NMR研究了小鼠大脑在急性缺血状态下能量代谢的特点,结扎带迷走神经的颈总动脉后,PCr/Pi、β-ATP/Pi比值迅速下降,且PCr/Pi下降速度较快,同时脑细胞内酸中毒加重.缺血5min后恢复供血,可部分地逆转缺血造成的损伤.     

用3lP NMR研究小鼠脑在缺氧状态下能量代谢的动态变化

用³¹P体内核磁共振方法无损伤地观察了C57小鼠脑在缺氧时与能量代谢有关的含磷化合物Pi,PCr,ATP的动态变化,当气体中氧气含量降到5%时,小鼠大脑的PCr,ATP逐渐减少,Pi不断增加,脑组织内pH值降低至6.83~6.93.当Pi与PCr的峰高比等于1时给予复氧,发现复氧时Pi立即降低且pH立即升高的小鼠可以恢复,反之则不可恢复,表明Pi和pH反映了大脑缺氧损伤程度.     

急性低氧大鼠脑31P核磁共振波谱研究

³¹P磁共振波谱是目前唯一可以用作在体无损伤的检测细胞水平能量代谢变化的非侵入性技术,可测得脑内多种能量代谢产物.目的：急性低氧大鼠脑组织的³¹P MRS检测.方法：(1)20只成年SD大鼠分为4组：低氧0min(对照),5min,10min,15min后,迅速液氮冷冻;(2)将脑组织研碎后,加入高氯酸(PCA),冷冻干燥;(3)将提取物用0.5mL D\-2O溶解后进行MRS检测.结果：(1)急性低氧早期即引起³¹P MRS中PCr和ATP峰降低,ADP和Pi峰增高,PCr/Pi和ATP/Pi降低,而ADP/ATP增高.可交换磷池(EPP)中PCr的正常值为42.4%,低氧5min后降到28.9%, ATP从33.8%降到19.2%,Pi从17.7%升到42.0%.(2)急性低氧时³¹P MRS中脑内磷酯分解代谢产物GPC、GPE含量增加,说明低氧早期脑内即有膜磷酯的分解增加.结论：³¹P磁共振波谱可用于脑低氧性疾病的诊断,我们波谱中最敏感的指标是PCr/Pi和ATP/Pi,尤其早期降低更为显著.     

大鼠急性缺血心肌31P磁共振波谱的基础研究

利用³¹P磁共振波谱（MRS）检测了急性缺血心肌组织提取物中高能磷酸化合物的变化. 方法：成年SD大鼠在心肌梗塞后0、5、 20、45 min后进行取材,梗塞区、边缘区及正常区的心肌组织经高氯酸萃取后进行高分辨MRS检测. 结果：梗塞区,缺血5 min PCr/Pi比值下降到对照组的12 ％;20 min ATP/Pi 比值下降至0.05,Pi/EPP比值上升至0.8;45 min 梗塞区PDE/ATP上升至1.93,与45 min心肌的不可逆损伤超微结构相吻合. 边缘区各代谢产物出现改变的程度要小于梗塞区,大于正常区. 正常区也有能量代谢的改变. 结论：心肌组织的³¹P MRS能够反映心肌缺血后心肌不同部位的动态能量代谢改变. PDE/ATP是判断心肌不可拟性损伤的可靠指标.     

活体动物代谢过程的31P NMR研究——方法与初步结果

利用表面线圈探头测得了小鼠大脑,大腿肌肉和肝脏的体内³¹P NMR谱图。观察到PCr,ATP,PME,PDE,P_i等化合物的共振峰,并确定了各谱峰的化学位移。由大脑的P_i化学位移计算得到其细胞内pH值为7.15.用差谱方法解决了因定位不准而造成的肝脏谱图不纯。观察了小鼠大脑在缺氧状态下的代谢变化过程。当O₂浓度降至2%时,PCr开始下降,降到1%时,P_i明显升高。从空气变化到1%的O₂含量,致使小鼠死亡,小鼠大脑的pH值从7.16降到6.46。     

Langendorff灌流心脏的31P NMR谱测定

测定了Langendorff灌流大鼠和兔心脏的³¹P NMR谱.观测到PCr、ATP、SP、P_i以及PME和GPC等含磷代谢物的共振峰,各谱峰之间实现了很好的分辨.在3~5min的累加时间内测得的图谱具有较好的S/N,可用于以上含磷代谢物的定量测定,以高能含磷化合物ATP和PCr相对峰强度以及冠脉流量的变化对灌流大鼠心脏代谢的稳定性进行了考察,结果表明,在本实验条件下大鼠心脏的能量储存至少可稳定2h,用所建方法以3min的时间间隔对同一大鼠心脏缺血21min及再灌注12min过程中心脏的³¹P NMR谱进行了连续跟踪测定,并初步观测了缺血及再灌注过程中心肌细胞内ATP、PCr与P_i之间的消长关系.     

惰性气体对HFCVD沉积金刚石气相基团的影响

发射光谱法是对等离子进行在线诊断的常用方法。在丙酮/H_2、丙酮/H_2/He和丙酮/H_2/Ar三种体系中,对热丝化学气相沉积金刚石薄膜过程中的等离子体进行了在线测量。研究了不同体积分数的惰性气体对等离子体中各活性基团强度的影响,以及CH,Hβ与C_2的相对强度的比值、电子温度的大小随惰性气体体积分数的变化关系。结果表明,各基团的强度随着惰性气体体积分数的增加呈现上升趋势,且加入同体积分数的氩气比加入氦气的影响更大;CH,Hβ与C_2的相对强度比值、电子温度随着惰性气体体积分数的增加而呈现下降趋势,且在丙酮/H_2/Ar体系中要比丙酮/H_2/He体系中小。     

超高压和酶抑制剂联合处理对荔枝果肉中过氧化物酶和果胶甲基酯酶的影响

 为了研究超高压与酶抑制剂联合处理对荔枝果肉中过氧化物酶（POD）和果胶甲基酯酶（PME）的影响，将荔枝（“淮枝”品种）果肉在两种酶抑制剂组合溶液（A：5 g/L柠檬酸+2.5 g/L L-抗坏血酸+5 g/L氯化钙；B：10 g/L柠檬酸+5 g/L L-抗坏血酸+10 g/L氯化钙）中分别浸泡10 min，并在100~400 MPa压力、10 ℃温度条件下处理30 min，采用分光光度法测定果肉中POD、PME的活性。结果表明：A、B两种组合处理能够明显钝化POD，但却显著激活了PME；超高压与A组合联合处理不能使POD、PME活性下降；超高压与B组合联合处理对POD、PME的影响与压力值有关系，100~300 MPa的超高压与B组合联合处理使POD活性下降，200~400 MPa的超高压与B组合联合处理则使PME活性升高。因此，超高压与酶抑制剂联合处理对荔枝果肉中POD的钝化存在一定的协同效应，且浓度越高，协同抑制效应越明显；而超高压与酶抑制剂联合处理对荔枝果肉中PME的钝化却表现出一定的拮抗性。     

大鼠脑缺血边缘区代谢物1H-MRS的研究

目的 利用不同的局灶性脑缺血模型，评价急性缺血后磁共振质子波谱（¹H-MRS）测定缺血后边缘区脑组织代谢和生物能量变化的时空规律. 为判定急性缺血预 后，进行有效的溶栓治疗提供有价值的生物化学信息. 方法 健康Sprague-Dawly大鼠9只，雌雄不拘，随机分为两组. A组（4只），自体血栓栓塞1 h；B组（5只），线栓法栓塞1 h. 分别 于栓塞后30、40、50、60 min进行¹HMRS检查，相对含量分析兴趣区（regio ns of interest, ROIs）氮-乙酰天门冬氨酸（NAA）、胆碱（Cho）和乳酸（Lac）等代谢产物的变化. 结果 以NAA、Cho、Lac与磷酸肌酸和肌酸（PCr+Cr）的谱峰积 分面积比值为判断标准，上述各代谢产物在兴趣区内于缺血后1 h内逐渐下降. 其中缺血后60 min，Cho/ （P Cr+Cr）、NAA/（PCr+Cr）及Lac/（PCr+Cr）的比值与缺血后50 min的比值统计学有显著性 差异（P<0.05）. 结论 ¹H-MRS技术为研究急性缺血性卒中后脑细胞代谢、生化能量状态提供了一个无创性、直接性、综合性的研究工具.     

Metabolite mapping of human filarial parasite, Brugia malayi with nuclear magnetic resonance

Metabolite mapping of human filarial parasite, Brugia malayi was carried out in vitro as well as in situ in host Mastomys coucha by ³¹P nuclear magnetic resonance (NMR) spectroscopy. Detection of parasites by visualizing contrast spots due to pathologic changes was observed by ¹H magnetic resonance imaging (MRI). Major metabolites of adult B. malayi observed by ³¹P-NMR spectroscopy were of sugar phosphates (SP), phosphomonoesters (PME), glycerophosphoryl-ethanolamine (GPE), -choline (GPC), phosphoenolpyruvate (PEP), inorganic phosphate (Pi), nucleoside diphosphosugar and nucleotides-mono, -di and -tri phosphates. PEP and GPC were present in high concentration; PEP being the major energy reservoir and GPC the major phospholipid in this species of filaria. The ³¹P NMR spectra of testis of mastomys, showed seven major peaks of SP, PME, phosphocreatine (PCr), phosphodiesters (PDE), Pi, and nucleotides di- and tri-phosphates. The ³¹P-NMR spectra of testis of B. malayi infected animal also consisted of seven major peaks with significant decrease in the SP and PME peak showing changes in the carbohydrate and lipid metabolism of filaria infected testis. Thus, in vivo ³¹P MRS provided a non-invasive assessment of tissue bioenergetics and phospholipid metabolism.     

Relayed magnetization transfer from nuclear Overhauser effect and chemical exchange observed by in vivo ³¹P MRS in rat brain

The ³¹P magnetization transfer effects among nuclear magnetic resonances (NMRs) of phosphocreatine (PCr), γ-adenosine-5'-triphosphate (γ-ATP) and inorganic phosphate (Pi) have been attributed to the chemical exchange reactions among PCr, ATP and Pi catalyzed by creatine kinase (CK) and ATPase enzymes and, therefore, are commonly applied in situ to measure chemical exchange fluxes involving two chemically coupled CK and ATPase reactions (i.e., PCr↔ATP↔Pi) by selectively saturating γ-ATP resonance. Besides the expected reductions in the Pi and PCr NMR signals upon saturating γ-ATP resonance, one particularly interesting phenomenon showing decreases in α-ATP and β-ATP signals was also observed. The underlying mechanism was investigated and identified via saturating NMR of β-ATP in the present study. The unique relayed magnetization transfer effects through spin diffusion were observed in the rat brain using in vivo ³¹P magnetic resonance spectroscopy.     

Observations of energy metabolism in neuroectodermal tumors using in vivo 31P-NMR

The energy metabolism of living tumors in rats and hamsters were investigated by obtaining in vivo 31P-NMR spectra, and the effects of chemotherapy on tumors were evaluated by observing the changes of these spectra. Tumor cells of rat glioma, human glioblastoma and human neuroblastoma were inoculated subcutaneously in the lumbar region of the animals. After the tumor grew to over 1.5 cm in diameter, in vivo 31P-NMR spectrum data was obtained selectively from the tumor with a TMR-32 spectrometer (Oxford Research Systems, U.K.). Several peaks (ATP, inorganic phosphate (Pi), phosphodiesters and phosphomonoesters (PME) were observed in the tumors. The heights of these peaks varied widely corresponding to the tumor growth. However, the spectrum pattern of each tumor in an active stage was found to be essentially the same regardless of histological type or tumor origin. The phosphocreatine (PCr) peak was small, ATP and PME peaks were large and tissue pH calculated from the chemical shift of Pi was low in each tumor group. After intravenous injection of a large dose of a chemotherapeutic agent, ATP peaks decreased and the Pi peak increased gradually, resulting in a dominant Pi peak pattern after several hours in all groups. With lower drug doses, spectrum changes were temporarily seen in the tumors. These findings indicated that drugs with a high dose have a selective and a direct action on the energy metabolism of tumor tissues. In vivo 31P-NMR spectra measurement is very valuable not only to investigate the energy metabolism in tumor tissue but also to evaluate the effects of chemotherapy on the tumor.     

In vivo (31)P MRS study of skeletal muscle metabolism in patients with postpolio residual paralysis

The muscle metabolism of at-rest patients with varying degrees of postpolio residual paralysis (PPRP) was studied and compared with that of controls using in vivo phosphorus magnetic resonance spectroscopy. The phosphocreatine (PCr)/inorganic phosphate (Pi) and PCr/adenosine triphosphate ratios were lower in patients than in controls. Reduction in PCr/Pi suggests abnormalities in oxidative phosphorylation. A significant increase was observed in the phosphomonoester/PCr ratio in patients, indicating the accumulation of intermediary compounds of the glycolytic pathway. Furthermore, the phosphodiester/PCr ratio was also significantly increased in patients. In general, the observed changes in metabolite ratios were found to be related to the degree of residual paralysis, suggesting that metabolic changes are secondary to chronic neurogenic processes. These metabolic alterations appear to be the possible cause of energy deficit and underlying muscle fatigue in PPRP patients. The present results provide an insight into the metabolic impairment and degree of muscle damage in patients with PPRP.     

Phosphorus-31 MR spectroscopic imaging (MRSI) of normal and pathological human brains.

The goals of this study were to evaluate 31P MR spectroscopic imaging (MRSI) for clinical studies and to survey potentially significant spatial variations of 31P metabolite signals in normal and pathological human brains. In normal brains, chemical shifts and metabolite ratios corrected for saturation were similar to previous studies using single-volume localization techniques (n = 10; pH = 7.01 +/- 0.02; PCr/Pi = 2.0 +/- 0.4; PCr/ATP = 1.4 +/- 0.2; ATP/Pi = 1.6 +/- 0.2; PCr/PDE = 0.52 +/- 0.06; PCr/PME = 1.3 +/- 0.2; [Mg2+]free = 0.26 +/- 0.02 mM.) In 17 pathological case studies, ratios of 31P metabolite signals between the pathological regions and normal-appearing (usually homologous contralateral) regions were obtained. First, in subacute and chronic infarctions (n = 9) decreased Pi (65 +/- 12%), PCr (38 +/- 6%), ATP (55 +/- 6%), PDE (47 +/- 9%), and total 31P metabolite signals (50 +/- 8%) were observed. Second, regions of decreased total 31P metabolite signals were observed in normal pressure hydrocephalus (NPH, n = 2), glioblastoma (n = 2), temporal lobe epilepsy (n = 2), and transient ischemic attacks (TIAs, n = 2). Third, alkalosis was detected in the NPH periventricular tissue, glioblastoma, epilepsy ipsilateral ictal foci, and chronic infarction regions; acidosis was detected in subacute infarction regions. Fourth, in TIAs with no MRI-detected infarction, regions consistent with transient neurological deficits were detected with decreased Pi, ATP, and total 31P metabolite signals. These results demonstrate an advantage of 31P MRSI over single-volume 31P MRS techniques in that metabolite information is derived simultaneously from multiple regions of brain, including those outside the primary pathological region of interest. These preliminary findings also suggest that abnormal metabolite distributions may be detected in regions that appear normal on MR images.     

Bio-energetic impairment in human calf muscle in thyroid disorders: a P MRS study

Mitochondrial metabolism particularly oxidative phosphorylation is greatly influenced by thyroid hormones. Earlier studies have described neuromuscular symptoms as well as impaired muscle metabolism in hypothyroid and hyperthyroid patients. In this study, we intend to look in to the muscle bioenergetics including phosphocreatine recovery kinetics based oxidative metabolism in thyroid dysfunction using in vivo ³¹P nuclear magnetic resonance spectroscopy (MRS). ³¹P MRS was carried out at resting state on 32 hypothyroid, 10 hyperthyroid patients and 25 control subjects. Nine out of 32 hypothyroid patients and 17 out of 25 control subjects under went exercise protocol for oxidative metabolism study and performed plantar flexion exercise while lying supine in 1.5 T magnetic resonance scanner using custom built exercise device. MRS measurements of inorganic phosphate (Pi), phosphocreatine (PCr), phosphodiesters (PDE) and adenosine triphosphate (ATP) of the calf muscle were acquired during rest, exercise and recovery phase. PCr recovery rate constant (k_PCr) and oxidative capacity were calculated by monoexponential fit of PCr versus time (t) at the beginning of recovery. During resting condition in hypothyroid patients, PCr/Pi ratio was reduced whereas PDE/ATP and Pi/ATP were increased. However, in case of hyperthyroidism, an increased PCr/Pi ratio and reduced PDE/ATP and Pi/ATP were observed. The results confirmed differential energy status of the muscle due to increased or decreased levels of thyroid hormone. Our results also demonstrate reduced oxidative metabolism in hypothyroid patients based on PCr recovery kinetics. PCr recovery kinetics study after exercise revealed decreased PCr recovery rate constant (k_PCr) in hypothyroid patients compared to controls that resulted in decrease in oxidative capacity of muscle by 50% in hypothyroids. These findings are consistent with a defect of high energy phosphate mitochondrial metabolism in thyroid dysfunction.