BACKGROUND: The C-reactive protein(CRP) is one of the "acute phase" proteins and it is known to be the most sensitive indicator of the inflammatory and/or necrotic process. Traditional methods for measuring CRP are capillary precipitation assay and latex agglutination assay. However, these methods have low sensitivity and provide only qualitative results. Recently the development of specific and very sensitive assays for CRP using highly specific monoclonal antibodies for CRP have done, including radioimmunoassay, nephelometric assay(NA), and turbidimetric immunoassay(TIA). We evaluated the Hitachi 7600-110(R)(Hitachi Co., Japan) using TIA in the measurement of CRP and compared its results to those of the the LX-M(R)(Eiken Chemical Co., Japan) using NA in order to replace the Hitachi 7600-110(R) for quantitative analysis of CRP. METHODS: CRP were measured by the Hitachi 7600-110(R) using TIA and the LX-M(R) using NA in the sera from 106 patients. The relationship between results of Hitachi 7600-110(R) and LX-M(R). By performing 20 repetitive assays at three levels of CRP control serum and pooled sera, within-run, within-day, and between-day precision of the Hitachi 7600-110(R) were established. RESULTS: When the CRP value of 4.60 +/- 5.65 mg/dL by the Hitachi 7600-110(R) was compared with that of 3.71 +/- 4.32 mg/dL by the LX-M(R), coefficients of correlation of 0.994 was obtained. The regression equation was Y(Hitachi 7600-110(R)) = 1.298 X(LX-M(R)) - 0.211(r=0.994, n=106). CVs of CRP measured by Hitachi 7600-110(R) were 5.45% at 0.82 mg/dL, 1.32% at 2.39 mg/dL, and 2.37% at 4.62 mg/dL. The precision was excellent in each group. The linearity was acceptable, and sample to sample carry-over was 0.8%. CONCLUSIONS: The Hitachi 7600-110(R) using TIA, compared with the LX-M(R) using NA, showed good coefficient of correlation and excellent precision. Therefore the Hitachi 7600-110(R) can replace the LX-M for quantitative analysis of CRP.
Agglutination ; Antibodies, Monoclonal ; C-Reactive Protein* ; Capillaries ; Humans ; Latex ; Radioimmunoassay

BACKGROUND: The opitmal ventilator setting during partial liquid ventilation(PLV) is controversial. This study investigated the effects of various gas exchange parameters during PLV in normal rabbit lungs in order to aid in the development of an optimal ventilator setting during PLV. METHODS: Seven New-Zealand white rabbits were ventilated in pressure-controlled mode with the following settings; tidal volume(VT) 8ml/kg, positive end-expiratory pressure(PEEP) 4cmH2O, inspiratory-to-expiratory ratio(I:E ratio) 1:2, fraction of inspired oxygen(F1O2) 1.0. The respiration rate(RR) was adjusted to keep PaCO2 between 35~45mmHg. The ventilator settings were changed every 30 min in the following sequence : (1) Baseline, as the basal ventilator setting, (2) Inverse ratio, I:E ratio 2:1, (3) high PEEP, adjust PEEP to achieve the same mean inspiratory pressure (MIP) as in the inverse ratio, (4) High VT, VT 15ml/kg, (5) high RR, the same minute ventilation(MV) as in the High VT. Subsequently, the same protocol was repeated after instilling 18ml/kg of perfluorodecalin for PLV. The parameters of gas exchange, lung mechanics, and hemodynamics were examined. RESULTS: (1) The gas ventilation(GV) group showed no significant changes in the PaO2 at all phases. The PaCO2 was lower and the pH was higher at the high VT and high RR phases(p<0.05). No significant changes in the lung mechnics and hemodynamics parameters were observed. (2) The baseline PaO2 for the PLV was 312+/-113mmHg. This was significantly lower when decreased compared to the baseline PaO2 for GV which was 504+/-81mmHg(p=0.001). During PLV, the PaO2 was significantly higher at the high PEEP(452+/-38mmHg) and high VT(461+/-53mmHg) phases compared with the baseline phase. However, it did not change significantly during the inverse I:E ratio or the high RR phases. (3) The PaCO2 was significantly lower at high VT and RR phases for both the GV and PLV. During the PLV, PaCO2 were significantly higher compared to the GV (p<0.05). (4) There were no important or significant changes in of baseline and high RR phases lung mechanics and hemodynamics parameters during the PLV. CONCLUSION: During PLV in the normal lung, adequate VT and PEEP are important for optimal oxygenation.
Hemodynamics ; Hydrogen-Ion Concentration ; Liquid Ventilation* ; Lung* ; Mechanics ; Oxygen ; Physiology ; Rabbits ; Respiration ; Ventilators, Mechanical