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Target Concepts:
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Query: UMLS:C0847097 (
acidity
)
15,165
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Since the conception of the pentavalent technetium polynuclear complex of dimercaptosuccinic acid, Tc(V)-
DMS
, a great number of papers published on its clinical applicability forced us to question "how tumor tissue appropriates the Tc(V)-
DMS
." Preliminary in vitro studies with Ehrlich ascites tumor cells (EATC) indicated the pH-sensitive character of this tumor agent. From this finding and the well-established notion that malignant tumors are more acidic than normal tissue, the in vivo correlation of Tc(V)-
DMS
accumulation in tumor tissue with its tissue acidification was considered of interest. The systemic lowering of tumor tissue pH by the stimulation of aerobic glycolysis has been well reported. In the present paper, the response of Tc(V)-
DMS
tumor accumulation to acidification induced by the glucose administration was explored in EATC-bearing mice. Measurement of tumor tissue pH was carried out by direct microelectrode technique and by histochemical umbelliferone technique in tumor tissue excised from EATC bearing mice. The regional
acidity
distribution is correlated with the regional radioactivity distribution registered by autoradiography. Evidence related to the pH sensitiveness of Tc(V)-
DMS
in response to glycolytic acidification was gathered; the pH measurement and the in vivo biodistribution of the double-tracer macroautoradiography with C-14 deoxyglucose (C-14-DG) demonstrated that the regional tissue distribution of Tc(V)-
DMS
was superimposed to that of C-14-DG. The glucose interventional modality offers the premier foundation for the interpretation of Tc(V)-
DMS
accumulation in diagnostic studies of malignant tumors.
...
PMID:Tc(V)-DMS tumor localization mechanism: a pH-sensitive Tc(V)-DMS-enhanced target/nontarget ratio by glucose-mediated acidosis. 975 22
The water exchange process on [(CO)(3)Re(H(2)O)(3)](+) (1) was kinetically investigated by (17)O NMR. The
acidity
dependence of the observed rate constant k(obs) was analyzed with a two pathways model in which k(ex) (k(ex)(298) = (6.3 +/- 0.1) x 10(-3) s(-1)) and k(OH) (k(OH)(298)= 27 +/- 1 s(-1)) denote the water exchange rate constants on 1 and on the monohydroxo species [(CO)(3)Re(I)(H(2)O)(2)(OH)], respectively. The kinetic contribution of the basic form was proved to be significant only at [H(+)] < 3 x 10(-3) M. Above this limiting [H(+)] concentration, kinetic investigations can be unambiguously conducted on the triaqua cation (1). The variable temperature study has led to the determination of the activation parameters Delta H(++)(ex) = 90 +/- 3 kJ mol(-1), Delta S(++)(ex) = +14 +/- 10 J K(-1) mol(-1), the latter being indicative of a dissociative activation mode for the water exchange process. To support this assumption, water substitution reaction on 1 has been followed by (17)O/(1)H/(13)C/(19)F NMR with ligands of various nucleophilicities (TFA, Br(-), CH(3)CN, Hbipy(+), Hphen(+),
DMS
, TU). With unidentate ligands, except Br(-), the mono-, bi-, and tricomplexes were formed by water substitution. With bidentate ligands, bipy and phen, the chelate complexes [(CO)(3)Re(H(2)O)(bipy)]CF(3)SO(3) (2) and [(CO)(3)Re(H(2)O)(phen)](NO(3))(0.5)(CF(3)SO(3))(0.5).H(2)O (3) were isolated and X-ray characterized. For each ligand, the calculated interchange rate constants k'(i) (2.9 x 10(-3) (TFA) < k'(I) < 41.5 x 10(-3) (TU) s(-1)) were found in the same order as the water exchange rate constant k(ex), the S-donor ligands being slightly more reactive. This result is indicative of I(d) mechanism for water exchange and complex formation, since larger variations of k'(i) are expected for an associatively activated mechanism.
...
PMID:Reactivity of the organometallic fac-[(CO)3ReI(H2O)3]+ aquaion. Kinetic and thermodynamic properties of H2O substitution. 1276 88
