Anti-idiotype monoclonal antibodies against emicizumab enable accurate procoagulant and anticoagulant assays, irrespective of the test base, in the presence of emicizumab.

INTRODUCTION: Emicizumab markedly shortens the activated partial thromboplastin time (aPTT), resulting in inaccurate measurements of procoagulant and anticoagulant factor activities. We have recently reported that mixtures of two different anti-idiotype monoclonal antibodies against emicizumab (anti-emicizumab-mAbs) allow measurement of factor (F)VIII activity (FVIII:C) and FVIII inhibitor in emicizumab-containing plasmas. It is unknown whether anti-emicizumab mAbs can work for other aPTT-based procoagulant and anticoagulant assays. AIM: To investigate whether anti-emicizumab mAbs were measured by all of the aPTT-based assays tested. METHODS: Two anti-emicizumab-mAbs (300 µg/mL each) were preincubated with emicizumab (200 µg/mL)-spiked FVIII-deficient plasma; we then measured FVIII:C, FIX:C, FXI:C, FXII:C, protein (P)C:C, PS:C, global PC-FV (aPTT-based), and prothrombin time (PT), diluted Russel's viper venom time (dRVVT), chromogenic-based FVIII:C, FIX:C and PC:C (non-aPTT-based). Emicizumab (100 µg/mL)-spiked haemophilia (H)A plasmas from patients (n = 23) were also measured. RESULTS: Emicizumab shortened the clotting time in all aPTT-based assays, resulting in high levels of FVIII:C, FIX:C, FXI:C and FXII:C; low levels of PC:C and PS:C; and false-positive results for activated PC resistance. The addition of anti-emicizumab-mAbs to emicizumab-added plasma restored all factors to the initial levels without emicizumab. Chromogenic FVIII:C measurement by human FIXa/FX was affected by emicizumab, but anti-emicizumab mAbs cancelled this effect. PT-based assays and dRVVT, chromogenic FIX:C and PC:C assays showed no effect with emicizumab. Twenty-three plasma samples from HA patients also showed similar patterns. CONCLUSION: Anti-emicizumab mAbs in vitro could cancel the effect of emicizumab, irrespective of the test base, resulting in accurate measurements of procoagulant and anticoagulant factor activity.

Supranormal orientation selectivity of visual neurons in orientation-restricted animals.

Altered sensory experience in early life often leads to remarkable adaptations so that humans and animals can make the best use of the available information in a particular environment. By restricting visual input to a limited range of orientations in young animals, this investigation shows that stimulus selectivity, e.g., the sharpness of tuning of single neurons in the primary visual cortex, is modified to match a particular environment. Specifically, neurons tuned to an experienced orientation in orientation-restricted animals show sharper orientation tuning than neurons in normal animals, whereas the opposite was true for neurons tuned to non-experienced orientations. This sharpened tuning appears to be due to elongated receptive fields. Our results demonstrate that restricted sensory experiences can sculpt the supranormal functions of single neurons tailored for a particular environment. The above findings, in addition to the minimal population response to orientations close to the experienced one, agree with the predictions of a sparse coding hypothesis in which information is represented efficiently by a small number of activated neurons. This suggests that early brain areas adopt an efficient strategy for coding information even when animals are raised in a severely limited visual environment where sensory inputs have an unnatural statistical structure.

Complex cells in the cat striate cortex have multiple disparity detectors in the three-dimensional binocular receptive fields.

Along the visual pathway, neurons generally become more specialized for signaling a limited subset of stimulus attributes and become more invariant to changes in the stimulus position within the receptive fields (RFs). One of the likely mechanisms underlying such invariance appears to be pooling of detectors located at different positions. Does such spatial pooling occur for disparity-selective neurons in primary visual cortex? To examine whether the three-dimensional (3D) binocular RFs are constructed by pooling detectors for binocular disparity, we investigated binocular interactions in the 3D space for neurons in the cat striate cortex. Approximately one-third of complex cells showed the spatial pooling of disparity detectors to a significant degree, whereas the majority of simple cells did not. The degree of spatial pooling of disparity detectors along the preferred orientation axis was generally larger than that along the axis orthogonal to the orientation axis. We then reconstructed 3D binocular RFs in their complete form and examined their structures. Disparity tuning curves were compared across positions along the orientation axis in the RFs. A small population of cells appeared to show a gradual shift of the preferred disparity along this axis, indicating that they can potentially signal inclination in the 3D space. However, the majority of cells exhibited a position-invariant disparity tuning. Finally, disparity tuning curves were examined for all oblique angles in addition to horizontal and vertical. Tunings were broadest along the orientation axis as the disparity energy model predicts.