Monoclonal antibody ERIC-1(Imperial Cancer Research Technology)

Murine monoclonal antibody (MoAb) ERIC-1 recognises an epitope on the neural cell adhesion molecule (NCAM) whose expression in paediatric and adult tissues is confined mainly to the brain, peripheral nerve, and adrenal medulla. Anti-NCAM antibodies have been used for the treatment and diagnosis of a number of tumours, including neuroblastoma. However, whole antibody exhibits poor penetration into solid tumour deposits and rapid systemic clearance upon repeated administration due to development of a human antimouse antibody (HAMA) response.

To overcome these problems, recombinant DNA techniques have been used to humanise and assemble the ERIC-1 immunoglobulin variable heavy (VH) and light (VL) chains into a single chain Fv (scFv).

Three humanised scFv clones were identified which differ from the predicted humanised sequence by occasional amino acid changes, but these maintain the same specificity as the original ERIC-1 MoAb.

The humanised scFv may prove to be a useful reagents in the treatment and diagnosis of a variety of neuroectodermal tumours and can clearly form a suitable template for the generation of a fully humanised ERIC-1 MoAb.

A pilot study of the treatment of patients with relapsed malignant gliomas with direct intratumoral injections of yttrium-90 (90Y) radioimmunoconjugates has been completed. Patients were recruited following maximal tumour resection, and received 1-3 injections of 90Y conjugated to a monoclonal antibody designated ERIC-1, which binds the neural cell-adhesion molecule. Data were collected to establish clinical toxicity, pharmacokinetics and radiation doses to the cavity wall and critical body organs. Twenty-three injections were completed in 15 patients, with a mean injected activity of 675 MBq (range 399-921). Early toxicity manifested as cerebral oedema and was readily controlled with dexamethasone. Delayed myelosuppression was observed but no intervention was required. Pharmacokinetic analysis confirmed prolonged retention of isotope in the cavity with correspondingly low activity in the bloodstream. These data were translated into estimates of absorbed radiation dose using the Medical Internal Radiation Dosimetry (MIRD) scheme. Mean doses, and dose rates, to the wall of the cavity, i.e. 'tumour,' were very high in comparison to normal tissue doses, with a further advantage if targeting was achieved.