Radiosynthesis of 68Ga-labelled DOTA-biocytin (68Ga-r-BHD) and assessment of its pharmaceutical quality for clinical use.

OBJECTIVES: Biocytin analogues labelled with indium-111, yttrium-90 and lutetium-177 have shown their effectiveness in the imaging of infections/inflammation in patients with osteomyelitis and function as efficient tools in pretargeted antibody-guided radioimmunotherapy. In this study, the labelling of a biocytin analogue coupled with DOTA (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid), namely, r-BHD, with gallium-68 (68Ga) was optimized, and the quality and stability of the preparations were assessed for clinical use. MATERIALS AND METHODS: Synthesis of 68Ga-r-BHD was carried out by heating a fraction of the 68Ge/68Ga eluate in a reactor containing the biocytin analogue with the appropriate buffer. The influence of the precursor amount (from 2.5 to 140 nmol), the pH of the reaction (from 2 to 5.5) and the buffer species (1.5 mol/l sodium acetate, 1.5 mol/l sodium formate, 4.5 mol/l HEPES) on radiochemical yield and radiochemical purity was assessed. Studies on stability and binding to avidin (Av) were also conducted in different media. RESULTS: Under the best labelling condition (56 nmol of precursor, 3.8 pH, sodium formate buffer) synthesis of 68Ga-r-BHD resulted in a yield of 64 ± 3% (not decay corrected). Radiochemical purity was around 95% because a 68Ga-coordinated sulfoxide form of the ligand was detected as a by-product of the reaction (68Ga-r-SBHD). The by-product was identified and characterized by liquid chromatography-electrospray ionization tandem mass spectrometry. At the natural 1 : 4 Av/68Ga-r-BHD molar ratio, affinity results were 62 ± 2 and 80 ± 2% in saline and human serum, respectively. Stability of 68Ga-r-BHD and of the radiotracer/Av complex remains almost constant over 180 min. 68Ga-r-BHD appears to be a good candidate for clinical applications.

A solid-phase mutual inhibition assay with labeled antigen.

A widely applicable method for the determination of the epitope specificities of a large number of monoclonal antibodies (MAbs) is presented. The method is based on the solid-phase mutual inhibition assay using 96-well plates coated with the respective MAbs, competitor MAbs, biotinylated antigen, and avidin-peroxidase conjugate. Using carcinoembryonic antigen (CEA) as a model antigen, the method was applied to determine epitope specificities of anti-CEA MAbs. A constant amount of biotinylated CEA was incubated with a given MAb immobilized on wells of 96-well plates in the presence of increasing amounts of soluble competitor MAbs. The biotinylated CEA bound to the immobilized antibody was then reacted with avidin-peroxidase conjugate and the activity of the bound peroxidase was determined by using o-phenylenediamine and hydrogen peroxide. The method used alleviates the laborious procedures of labeling all antibodies to be tested and the confusion caused by differential labeling among different MAbs. It is a convenient method for mapping analysis of many MAbs if the corresponding purified antigen is available.

Dynamic strength of molecular adhesion bonds.

In biology, molecular linkages at, within, and beneath cell interfaces arise mainly from weak noncovalent interactions. These bonds will fail under any level of pulling force if held for sufficient time. Thus, when tested with ultrasensitive force probes, we expect cohesive material strength and strength of adhesion at interfaces to be time- and loading rate-dependent properties. To examine what can be learned from measurements of bond strength, we have extended Kramers' theory for reaction kinetics in liquids to bond dissociation under force and tested the predictions by smart Monte Carlo (Brownian dynamics) simulations of bond rupture. By definition, bond strength is the force that produces the most frequent failure in repeated tests of breakage, i.e., the peak in the distribution of rupture forces. As verified by the simulations, theory shows that bond strength progresses through three dynamic regimes of loading rate. First, bond strength emerges at a critical rate of loading (> or = 0) at which spontaneous dissociation is just frequent enough to keep the distribution peak at zero force. In the slow-loading regime immediately above the critical rate, strength grows as a weak power of loading rate and reflects initial coupling of force to the bonding potential. At higher rates, there is crossover to a fast regime in which strength continues to increase as the logarithm of the loading rate over many decades independent of the type of attraction. Finally, at ultrafast loading rates approaching the domain of molecular dynamics simulations, the bonding potential is quickly overwhelmed by the rapidly increasing force, so that only naked frictional drag on the structure remains to retard separation. Hence, to expose the energy landscape that governs bond strength, molecular adhesion forces must be examined over an enormous span of time scales. However, a significant gap exists between the time domain of force measurements in the laboratory and the extremely fast scale of molecular motions. Using results from a simulation of biotin-avidin bonds (Izrailev, S., S. Stepaniants, M. Balsera, Y. Oono, and K. Schulten. 1997. Molecular dynamics study of unbinding of the avidin-biotin complex. Biophys. J., this issue), we describe how Brownian dynamics can help bridge the gap between molecular dynamics and probe tests.

Analysis of protein binding to receptor-doped lipid monolayers by Monte Carlo simulation.

This paper presents a Monte Carlo simulation (MCS) method for estimating the parameters that characterize ligand-receptor binding directly from experimentally derived binding isotherms. Binding parameters are estimated by incorporating an MCS algorithm for ligand binding to a two-dimensional receptor array into a nonlinear regression program. The MCS method was tested by analyzing experimental isotherms of avidin binding to biotinylated lipid in Langmuir-Blodgett (LB) monolayers. The MCS-derived cooperativity coefficients and intrinsic association constants for avidin-biotin binding to LB films are correlated strongly (R2 > 0.93) with the binding parameters determined from the same experimental data by a thermodynamic equilibrium binding model (Zhao et al. 1993. Langmuir. 9:3166-3173). This result shows MCS to be an accurate and potentially more versatile method for characterizing biomolecular interactions at surfaces.

Biotin assessment in foods and body fluids by a protein binding assay (PBA).

The biotin content of plant and animal food samples as well as of human plasma and urine specimens was assessed by a modified protein binding assay (PBA). Protein bound biotin in samples was released by digestion with papain, food samples were in addition treated previously with liquid nitrogen. Comparing analyses by use of the conventional microbiological test with L. plantarum resulted in slightly enhanced biotin values, in case of plasma by 9.2% and in case of urine by 10.3%, but the results obtained by both methods correlated well (r = 0.926 for plasma and 0.934 for urine). Regarding food analysis the additional comparison of different disintegration procedures led to best reproducible results by using the PBA with preceding papain digestion.