Michael J. Adam

Positron emission tomography in the early diagnosis of Huntington's disease

We studied 10 patients with early Huntingtons disease and 7 normal age-matched controls with positron emission tomography (PET) using fluorodeoxyglucose. Subjects had little or no caudate nucleus atrophy and had not received any medications. The results demonstrated that hypometabolism of glucose preceded tissue loss. Furthermore, patients with minimal neurologic or psychiatric symptoms and no obvious CT changes may be differentiated from normal persons with high accuracy by PET. PET is helpful in the early diagnosis of Huntingtons disease irrespective of the mode of presentation. PET may also be useful for preclinical detection and may supplement information from DNA studies.

Toward [18F]-labeled aryltrifluoroborate radiotracers: in vivo positron emission tomography imaging of stable aryltrifluoroborate clearance in mice.

The use of a boronic ester as a captor of aqueous [(18)F]-fluoride has been previously suggested as a means of labeling biomolecules in one step for positron emission tomography (PET) imaging. For this approach to be seriously considered, the [(18)F]-labeled trifluoroborate should be humorally stable such that it neither leaches free [(18)F]-fluoride to the bone nor accumulates therein. Herein, we have synthesized a biotinylated boronic ester that is converted to the corresponding trifluoroborate salt in the presence of aqueous [(18)F]-fluoride. In keeping with its in vitro aqueous kinetic stability at pH 7.5, the trifluoroborate appears to clear in vivo quite rapidly to the bladder as the stable trifluoroborate salt with no detectable leaching of free [(18)F]-fluoride to the bone. When this labeled biotin is preincubated with avidin, the pharmacokinetic clearance of the resulting complex is visibly altered. This work validates initial claims that boronic esters are potentially useful as readily labeled precursors to [(18)F]-PET reagents.

The Metabolism of [18F]6‐Fluoro‐l‐3,4‐Dihydroxyphenylalanine in the Hooded Rat

Abstract: The metabolism of the positron‐emitting compound [18F]6‐fluoro‐l‐3,4‐dihydroxyphenylalanine (*F‐DOPA) was studied in carbidopa‐pretreated male hooded rats. Thirty minutes following carbidopa administration (5 mg/kg i.p.), animals received *F‐DOPA (500 μg/kg; specific activity, 175–230 Ci/mol) as an intrajugular bolus. Blood samples were taken at various times between 5 and 90 min, and the plasma was analyzed by HPLC with gamma counting of fractions. *F‐DOPA disappeared rapidly from plasma in concert with the formation of the 3‐O‐methylated metabolite, Me‐*F‐DOPA. Animals were killed from 5 to 120 min after injection, and the brains were rapidly dissected. The disappearance of *F‐DOPA from both vermis and striatal samples was rapid. Me‐*F‐DOPA, the sole metabolite observed in the vermis, was the major labeled material in the striatum at ≥20 min after injection. Fluorodopamine was an important metabolite in the striatum, making up 25% of total radioactivity at early intervals. Striatal samples also contained fluoro‐3,4‐dihydroxyphenylacetic acid, which constituted ∼10% of the total radioactivity, and traces of two radiolabeled compounds, tentatively identified as fluorohomovanillic acid and fluoro‐3‐methoxytyramine.

Acyclic Chelate with Ideal Properties for 68Ga PET Imaging Agent Elaboration

We have investigated novel bifunctional chelate alternatives to the aminocarboxylate macrocycles NOTA (N(3)O(3)) or DOTA (N(4)O(4)) for application of radioisotopes of Ga to diagnostic nuclear medicine and have found that the linear N(4)O(2) chelate H(2)dedpa coordinates (67)Ga quantitatively to form [(67)Ga(dedpa)](+) after 10 min at RT. Concentration-dependent coordination to H(2)dedpa of either (68)Ga or (67)Ga showed quantitative conversion to the desired products with ligand concentrations as low as 10(-7) M. With (68)Ga, specific activities as high as 9.8 mCi nmol(-1) were obtained without purification. In a 2 h competition experiment against human apo-transferrin, [(67)Ga(dedpa)](+) showed no decomposition. Two bifunctional versions of H(2)dedpa are also described, and these both coordinate to (67)Ga at RT within 10 min. Complete syntheses, characterizations, labeling studies, and biodistribution profiles of the (67)Ga complexes are presented for the new platform chelates. The stability of these platform chelates is higher than that of DOTA.

Substituent Effects on Aryltrifluoroborate Solvolysis in Water: Implications for Suzuki−Miyaura Coupling and the Design of Stable 18F-Labeled Aryltrifluoroborates for Use in PET Imaging

Whereas electron withdrawing substituents retard the rate of aryltrifluoroborate solvolysis, electron-donating groups enhance it. Herein is presented a Hammett analysis of the solvolytic lability of aryltrifluoroborates where log(k(solv)) values correlate to sigma values with a rho value of approximately -1. This work provides a predictable rubric for tuning the reactivity of boron for several uses including (18)F-labeled PET reagents and has mechanistic implications for ArBF(3)-enhanced ligandless metal-mediated cross coupling reactions with aryltrifluoroborates.

Novel Matrix Metalloproteinase Inhibitor [18F]Marimastat-Aryltrifluoroborate as a Probe for In vivo Positron Emission Tomography Imaging in Cancer

Matrix metalloproteinases (MMP), strongly associated pathogenic markers of cancer, have undergone extensive drug development programs. Marimastat, a noncovalent MMP inhibitor, was conjugated with FITC to label cellular metalloproteinase cancer targets in MDA-MB-231 cells in vitro. Punctate localization of active transmembrane MMP14 was observed. For molecular-targeted positron emission tomography imaging of syngeneic 67NR murine mammary carcinoma in vivo, marimastat was (18)F-labeled using a shelf-stable arylboronic ester conjugate as a captor for aqueous [(18)F]fluoride in a novel, rapid one-step reaction at ambient temperature. [(18)F]Marimastat-aryltrifluoroborate localized to the tumors, with labeling being blocked in control animals first loaded with >10-fold excess unlabeled marimastat. The labeled drug cleared primarily via the hepatobiliary and gastrointestinal tract, with multiple animals imaged in independent experiments, confirming the ease of this new labeling strategy.

Cerebral Glucose Metabolism in Parkinson’s Disease

Local cerebral glucose utilization was measured in patients with predominantly unilateral Parkinsons disease using 18F-2-fluoro-deoxyglucose and positron emission tomography. Preliminary results indicate the presence of asymmetric metabolic rates in the inferior basal ganglia. The structure comprising the largest portion of basal ganglia at this level is globus pallidus. These findings are consistent with metabolic studies on animals with unilateral nigrostriatal lesions in which pallidal hypermetabolism on the lesioned side has been demonstrated. Increased pallidal activity is likely secondary to a loss of inhibitory dopaminergic input to the striatum from substantia nigra.

N-Aryl-substituted 3-(β-D-glucopyranosyloxy)-2-methyl-4(1H)-pyridinones as agents for Alzheimer's therapy

Molecules designed to sequester, redistribute and/or remove metal ions are attractive therapeutic agents in neurodegenerative diseases such as Alzheimers disease. The multifactorial nature of the condition and the generally poor target specificity associated with metal ion-binding therapy has led to the development of multifunctional 3-hydroxy-4-(1H)-pyridinone pro-ligands. The excellent qualities of the basic 3-hydroxy-4-pyridinone framework as a low toxicity metal chelator and an antioxidant, as well as its antibacterial and analgesic properties among other functions, inspired us to functionalize it with a framework derived from thioflavin-T, the well-known traditional dye used as a marker to detect amyloid deposits in tissue sections. Thus 2-methyl-3-hydroxy-1-(4-dimethylaminophenyl)-4(1H)-pyridinone (HL1), 2-methyl-3-hydroxy-1-(4-methylaminophenyl)-4(1H)-pyridinone (HL2), 1-(4-aminophenyl)-3-hydroxy-2-methyl-4(1H)-pyridinone (HL3), 1-(6-benzothiazolyl)-3-hydroxy-2-methyl-4(1H)-pyridinone (HL4), 1-(2-benzothiazolyl)-3-hydroxy-2-methyl-4(1H)-pyridinone (HL5) and 2-methyl-3-hydroxy-1-[4-(4-bromophenyl)-2-thiazolyl]-4(1H)-pyridinone (HL6) were obtained. Glycosylation, as well as incorporation of structures mimicking those of known amyloid imaging agents, may target drug action to the site of interest, the metal-overloaded amyloid plaques in the Alzheimers brain. The pro-ligands were assessed for their antioxidant activity, cytotoxicity and ability to interfere with metal ion-induced amyloid peptide aggregation to screen promising lead compounds. Finally, in a brain uptake study with a radiolabeled glucoconjugate pyridinone, 3-(β-D-glucopyranosyloxy)-1-[4-(4-[125I]iodophenyl)-2-thiazolyl]-2-methyl-4(1H)-pyridinone ([125I]-GL7) was shown to cross the blood–brain barrier using an in situ rat brain perfusion technique.

Stoichiometric leverage: rapid 18F-aryltrifluoroborate radiosynthesis at high specific activity for click conjugation.

,values which are higher than those of most other radiotracers.Herein,weshowthefeasibilityofthismethodintermsofone-step labeling and click conjugation, along with experimentalproof of such high SAs.Propargylated arylborimidine 1 was synthesized accord-ing to previous reports as a shelf-stable B(dan)-protected

RGD conjugates of the H2dedpa scaffold: synthesis, labeling and imaging with 68Ga

INTRODUCTION The rekindled interest in the (68)Ga generator as an attractive positron emission tomography generator system has led us and others to investigate novel chelate systems for (68)Ga. We have previously reported our findings with the acyclic, rapidly coordinating chelate H(2)dedpa and its model derivatives. METHODS In this report, we describe the synthesis of the corresponding bifunctional chelate scaffolds (H(2)dp-bb-NCS and H(2)dp-N-NCS) as well as the radiolabeling properties, transferrin stability, binding to the target using in vitro cell models and in vivo behavior the corresponding conjugates with the α(v)β(3) targeting cyclic pentapeptide cRGDyK (monomeric H(2)RGD-1 and dimeric H(2)RGD-2). RESULTS The ability of the conjugated ligands to coordinate Ga isotopes within 10 min at room temperature at concentrations of 1 nmol was confirmed. Complex [(67)Ga(RGD-1)](+) was more stable (92% after 2 h) than [(67)Ga(RGD-2)](+) (73% after 2 h) in a transferrin challenge experiment. IC(50) values for both conjugates (H(2)RGD-1 and H(2)RGD-2) and nonconjugated RGD were determined in a cell-based competitive binding assay with (125)I-echistatin using U87MG cells, where enhanced specific binding was observed for the multivalent H(2)RGD-2 conjugate compared to the monovalent H(2)RGD-1 and nonconjugated cRGDyK. The U87MG cell line was also used to generate subcutaneous xenograft tumors on RAG2M mice, which were used to evaluate the in vivo properties of [(68)Ga(RGD-1)](+) and [(68)Ga(RGD-2)](+). After 2 h of dynamic imaging, both block and nonblock mice were sacrificed to collect select organs at the 2-h time point. Although the uptake is specific, as judged from the ratios of nonblock to block (2.36 with [(67)Ga(RGD-1)](+), 1.46 with [(67)Ga(RGD-2)](+)), both conjugates display high uptake in blood. CONCLUSIONS We have successfully synthesized and applied the first bifunctional versions of H(2)dedpa for conjugation to a targeting vector and subsequent imaging of the corresponding conjugates.