Six cobalamin-biotin conjugates have been prepared. The cobalamin-biotin conjugates were prepared to evaluate the effect that the location of attachment had on the binding with transcobalamin II (TCII), the cobalamin binding protein in plasma, and to evaluate their potential use for in vitro and in vivo applications. This study focused only on the effect of binding with TCII. To decrease the possibility of steric problems in binding of the cobalamin conjugates with TCII, and biotin's binding with streptavidin or avidin, moieties of 11-18 atoms in length were used as linkers. Four biotin conjugates were prepared which were attached to the corrin ring of the cobalamin molecule (on b-, c-, d-, and e-side chains). One conjugate was attached to the 5'-OH of the ribose moiety, and another conjugate was attached at the cobalt metal (in place of the cyanide moiety of cyanocobalamin). Competitive binding studies were conducted where various amounts of the cobalamin-biotin conjugates and their precursor cobalamin derivatives competed with [57Co]cyanocobalamin for binding of recombinant human TCII (rhTCII). Evaluation of cobalamin derivatives which were conjugated at the 5'-OH of ribose or the cobalt metal center indicated that conjugation at either of these positions had little effect on binding with rhTCII. However, conjugates where the attachment was made on the corrin ring substituents had a large variation in binding with rhTCII. Conjugates on the e-propionamide side chain had little effect (relative affinity was equal to or decreased less than a factor of 3) on binding with rhTCII, conjugates of the b-isomer had decreased binding (relative affinity decreased less than a factor of 10), conjugates of the d-propionamide had further decreased binding (relative affinity decreased between 44 and 69 times), and conjugates on the c-acetamide group had poor binding to rhTCII (relative affinity decreased between 295 and 1160 times). The significance of the side chains on the corrin ring in providing specificity and high-affinity binding with rhTCII is discussed.
An investigation has been conducted to assess the in vivo stability of a series of astatinated benzamides and astatinated nido-carborane compounds in mice. It was hypothesized that the higher bond strength of boron-astatine bonds in the nido-carboranes might provide increased stability toward in vivo deastatination. Four tri-n-butylstannylbenzamides were prepared for radiohalogenation and evaluation in vivo. Those compounds were N-propyl-4-(tri-n-butylstannyl)benzamide 1a, N-propyl-3-(tri-n-butylstannyl)benzamide 2a, ethyl 4-tri-n-butylstannylhippurate 3a, and 4-tri-n-butylstannyl-hippuric acid 4a. Seven mono-nido-carboranyl derivatives were prepared for radiohalogenation and in vivo evaluation. Four of the seven mono-carboranyl derivatives (5a, 6a, 7a, 13a) contained a 3-(nido-carboranyl)propionamide functionality, and the remaining compounds (8a, 8g, 10a) contained a 4-(nido-carboranyl)aniline functionality. Two additional derivatives (11a, 12a) were prepared that contained bis-(nido-carboranylmethyl)benzene moieties (also referred to as Venus flytrap complexes (VFCs). All benzamide and nido-carborane compounds underwent facile iodination and radiohalogenation, except a 4-(nido-carboranyl)aniline derivative, 8a. Iodination of 8a resulted in a mixture, of which the desired iodinated product was a minor component. Therefore, radiohalogenation was not attempted. It is believed that the mixture of products is due to the presence of a thiourea bond. Previous studies have shown that thiourea bonds can interfere with halogenation reactions. In vivo comparisons of the compounds were conducted by co-injection of dual labeled (125/131I and 211At) compounds. Tissue distribution data were obtained at 1 and 4 h postinjection of the radiolabeled compounds, as that was sufficient to determine if astatine was being released. Stability of the astatinated compound was assessed by the difference in concentration of radioiodine and astatine in lung and spleen. All of the benzamides were found to undergo rapid deastatination in vivo. The nido-carborane derivatives appeared to be slightly more stable to in vivo deastatination; however, they had long blood residence times. The surprising finding was that the VFC derivatives did not release 211At in vivo, even though they rapidly localized to liver. This finding provides encouragement that stable conjugates of 211At may be attained if appropriate modifications of the VFC can be made to redirect their excretion through the renal system.
In this investigation, studies were conducted to determine if size exclusion HPLC could be used to assess relative association rates (on-rates) and dissociation rates (off-rates) of biotin derivatives from avidin (Av) and streptavidin (SAv). For easy detection and quantification of biotin derivatives, molecules that can be detected by UV absorbance were conjugated to biotin. Concern that conjugation of the chromophoric moieties (dyes) might affect biotin binding with Av and SAv or might interact with the HPLC column led to evaluation of 10 biotin-dye conjugates. The dyes conjugated with biotin included dansyl, cyanocobalamin (CN-Cbl), coumarin 343, Lissamine-rhodamine, fluorescein, Cascade Blue, Lucifer Yellow, Oregon Green, tetramethylrhodamine, and Alexa Fluor 594. The biotin-dye conjugates were initially evaluated to determine their peak characteristics on two different size exclusion HPLC columns. Measurement of the percent of biotin-dye conjugate bound with Av in the presence of an equal quantity of biotin provided an association rate relative to biotin. All of the biotin-dyes tested had association rates within a factor of 3x (slower) that of biotin. The relative dissociation rate of biotin-dye conjugates was assessed by challenging the biotin conjugate bound to Av or SAv with a large excess of biotin. All of the initial biotin-dye conjugates tested bound Av and SAv tightly resulting in very slow dissociation rates. From the biotin-dye conjugates studied, biotin-CN-Cbl, 6b, was selected as the best conjugate for the HPLC assay. To test the HPLC assay, an iminobiotin-CN-Cbl conjugate, 13a, and a biotin-sarcosine-CN-Cbl conjugate, 13b, were synthesized. The fact that the iminobiotin does not bind with Av at physiological pH was easily detected in the size exclusion HPLC assay. The biotin-sarcosine-CN-Cbl conjugate was expected to have a more rapid dissociation rate than the other biotin-dye conjugates. This was confirmed in that HPLC assay. Although 13b bound tightly with Av in the absence of added biotin, it was completely released within 1 h when challenged by an excess of biotin. A slower dissociation of 13b was noted with SAv. The results obtained indicate that CN-Cbl conjugates of biotin derivatives can be used to determine relative on-rates and off-rates of biotin derivatives with Av and SAv. The studies also demonstrated that the biotin-CN-Cbl conjugate, 6b, can be used as a reference compound to compare on-rates and off-rates of nonchromophoric biotin derivatives.
For selected patients, axillary lymph node dissection appears to have little influence on subsequent management and long-term outcome. These data suggest that it is time to reassess the role of axillary lymph node dissection in patients who undergo conservative surgery and radiation therapy.
Several cobalamin (Cbl) dimers have been prepared for evaluation as potential antiproliferative agents in the treatment of AIDS-related lymphoma. The Cbl dimers were synthesized by cross-linking Cbl carboxylates, produced by acid hydrolysis of the b-, d-, and e-propionamide side chains of cyanocobalamin (CN-Cbl), through an isophthalate molecule. Linking molecules were used between the Cbl carboxylates and the isophthalate moiety. The linkers were incorporated to provide a distance between the two Cbl molecules such that the dimeric Cbls might bind two molecules of transcobalamin II (TCII), the Cbl transport protein in plasma. Initially, the linking moiety used was 1,12-diaminododecane, but the resulting dimers had low aqueous solubility. To improve the solubility of the dimers, 4,7,10-trioxa-1,13-tridecanediamine was employed as the linking moiety. This improved the water solubility of the dimers considerably, while retaining the distance between the Cbl molecules at 41-42 A (fully extended). To introduce additional substitution on Cbl dimers, 5-aminoisophthalic acid was used as the cross-linking reagent. p-Iodobenzoyl and p-(tri-n-butylstannyl)benzoyl conjugates of 5-aminoisophthalate were synthesized and used to prepare Cbl dimers. The stannylbenzoyl-conjugated Cbl dimers were prepared as precursors to be used in radioiodination reactions, and the iodobenzoyl-conjugated Cbl dimers were prepared as HPLC standards for the radioiodinated product. Attempts to iodinate/radioiodinate the stannylbenzoyl Cbl dimers were unsuccessful. Although an explanation for this is not readily apparent, the failure to react may be due to the lipophilicity of the linker used and the steric environment of the two Cbl moieties. A biotinylated derivative of 5-aminoisophthalate was also synthesized and used to prepare biotinylated-Cbl dimers. In a competitive rhTCII binding assay with [57Co]CN-Cbl, Cbl dimers containing the lipophilic diaminododecane linking moiety had decreased binding avidities compared to those of Cbl monomers substituted at the same corrin ring carboxylate. However, Cbl dimers containing the water-solubilizing trioxadiamine linker appeared to have avidities similar to those of the Cbl monomers.
Previous studies have shown that the procedure-induced prostate edema during permanent interstitial brachytherapy (PIB) can cause significant variations in the dose delivered to the prostate gland. Because the clinical impact of edema-induced dose variations depends strongly on the magnitude of the edema, the temporal pattern of its resolution and its interplay with the decay of radioactivity and the underlying biological processes of tumor cells (such as tumor potential doubling time), we investigated the impact of edema-induced dose variations on the tumor cell survival and tumor control probability after PIB with the 131Cs, 125I and 103Pd sources used in current clinical practice. The exponential edema resolution model reported by Waterman et al. (Int. J. Radiat. Oncol. Biol. Phys. 41, 1069–1077–1998) was used to characterize the edema evolutions observed previously during clinical PIB for prostate cancer. The concept of biologically effective dose (BED), taking into account tumor cell proliferation and sublethal damage repair during dose delivery, was used to characterize the effects of prostate edema on cell survival and tumor control probability. Our calculation indicated that prostate edema, if not taken into account appropriately, can increase the cell survival and decrease the probability of local control of PIB. The edema-induced increase in cell survival increased with increasing edema severity, decreasing half-life for radioactive decay and decreasing energy of the photons energy emitted by the source. At the doses currently prescribed for PIB and for prostate cancer cells characterized by nominal radiobiology parameters recommended by AAPM TG-137, PIB using 125I sources was less affected by edema than PIB using 131Cs or 103Pd sources due to the long radioactive decay half-life of 125I. The effect of edema on PIB using 131Cs or 103Pd was similar. The effect of edema on 103Pd PIB was slightly greater, even though the decay half-life of 103Pd (17 days) is longer than that of 131Cs (9.7 days), because the advantage of the longer 103Pd decay half-life was negated by the lower effective energy of the photons it emits (~21 keV compared to ~30.4 keV for 131Cs). In addition, the impact of edema could be reduced or enhanced by differences in the tumor characteristics (e.g. potential tumor doubling time or the α/β ratio), and the effect of these factors varied for the different radioactive sources. There is a clear need to consider the effects of prostate edema during the planning and evaluation of permanent interstitial brachytherapy treatments for prostate cancer.
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