Tomoko Adachi

β2-microglobulin decrease in cerebrospinal fluid from parkinsonian patients

A sandwich enzyme immunoassay (EIA) was established by using purified beta 2-microglobulin (beta 2-MG) as a standard protein and a polyclonal antibody raised against human beta 2-MG. The EIA was applied for the measurement of beta 2-MG levels in human cerebrospinal fluid (CSF) from parkinsonian patients and control patients devoid of neurological diseases. beta 2-MG contents in CSF of the control group and the parkinsonian group were 1.81 +/- 0.11 micrograms/ml CSF and 0.63 +/- 0.09 microgram/ml CSF, respectively. Thus, beta 2-MG content in CSF was reduced in parkinsonian patients to less than 35% of the control value (P less than 0.005). We had previously reported that the activity and content of dopamine beta-hydroxylase (DBH) were decreased in CSF from parkinsonian patients. A significant positive correlation (r = 0.87) was observed between the beta 2-MG content and DBH activity for CSF from 45 patients. These results suggest a probable link between an immunological change and the changes in catecholaminergic neurons in Parkinsons disease.

Selective removal of β2-microglobulin from human plasma by high-performance immunoaffinity chromatography

We have used HPIAC to remove specifically B2-MG from human plasma. In this report, studies are described that were undertaken to determine the applicability and effectiveness of HPIAC on a column (affi-Prep 10) bearing immobilized anti-B2-MG immunoglobulin G (igG) as a procedure for plasma B2-MG elimination.

Selective removal of immunoglobulin E from rat blood by membrane-immobilized antibody

We examined the suitability of an immunoaffinity membrane [rabbit IgG specific for rat immunoglobulin E (IgE) immobilized on a cellulose membrane] for removing IgE from rat blood passed through a simple extracorporeal circulatory system. To determine the concentration of IgE in the blood, we also developed a highly sensitive chemiluminescence enzyme immunoassay for rat IgE. The IgE levels in the outlet blood from the immunoaffinity membrane module decreased to 30% of the initial concentration within 30 min.

Selective removal of human serum amyloid P component from rat blood by use of an immunoaffinity membrane in an extracorporeal circulation system

We examined the suitability of an immunoaffinity membrane (IAM) bearing specific antibody as a ligand for removing human serum amyloid P component (hSAP) from blood passed through a simple extracorporeal circulation system established in rats. The specific antibody was the most effective of the various ligands tested for removing hSAP from human blood. To determine the value of the hSAP in human or rat plasma, we also developed a simple ELISA. In the rat extracorporeal circulation system, the hSAP level in the inlet blood to the IAM module decreased to 49% of the initial concentration within 60 min. In contrast, the hSAP remained at the initial concentration throughout the study in the module without the IAM. The use of this extracorporeal circulation system in this case allows preclinical evaluation of the ex vivo removal of a human plasma component in an animal model. Biocompatibility of the IAM was also examined. No change in blood cell counts or activation of the coagulation system occurred after contact with the IAM. Non-specific adsorption was not observed, since there was no statistically significant difference in IgG, complement C3, or albumin level between the pre- and post-treatment with this module. The immunological effects of the IAM were also examined using this system. Four weeks after the termination of the extracorporeal circulation, the rats examined showed no detectable antibody titer to the ligand.

Rat extracorporeal circulation model for evaluation of systemic immunotoxicity

We have applied a rat extracorporeal circulation (EC) model as an evaluation system for the immunotoxicity of medical devices in contact with the blood stream. Combining popular hemodialysis (HD) membranes [a non-biocompatible membrane, Cupurophane (CUP), and more biocompatible membranes, Cu-ammonium rayon (CAR) and polyacrylonitrile (PAN)] with rat EC, we evaluated the elicitation of acute and delayed immunological responses, as well as the effect of repeated EC. Acute effect markers such as the production of tumor necrosis factor (TNF)-alpha and complement activity during EC, and delayed effect markers such as beta2-microglobulin (beta2-M), IgG, and complement 3 levels, were monitored. Acute markers after EC passage showed responses similar to those previously reported in patients with long-term hemodialysis such as TNF-alpha production and increased complement activity. Although beta2-M and IgG levels increased to 3- to 5-fold of the initial concentration within 4 weeks after rat EC, the trend of IgG increase was inversely correlated with membrane biocompatibility (CUP > CAR = PAN), but this did not occur for elevations in beta2-M (PAN > CAR > CUP). These data suggest that this EC model can reproduce similar immunological responses as seen in HD patients, and can be employed to evaluate medical devices and materials for their delayed, systemic, and repeated exposure effects with respect to immunotoxicity.