De pupilreactie belicht: Klinische aspecten van de normale en abnormale pupilreactie [= Clinical aspects of the abnormal pupillary response; shedding light on pupillary response]

Testing the pupillary response is a quick and valuable diagnostic measure for certain neurological and ophthalmological diseases in patients. The pupillary response can aid in localizing abnormalities in important parts of the visual system and brainstem, provided that the tests are executed and interpreted correctly. When an abnormal pupillary response is found, it is important to differentiate between an afferent problem (eyeball, retina, optical nerve), brain stem pathology, or an efferent problem (parasympathetic fibers of the oculomotor nerve, iris sphincter muscle). We describe the technique of the ophthalmological examination, the normal neurophysiology and the possible abnormal pupil responses in patients with intact and decreased consciousness

IgG4+ B-Cell receptor clones distinguish IgG4-related disease from primary sclerosing cholangitis and biliary/pancreatic malignancies.

IgG4-related disease of the biliary tree and pancreas is difficult to distinguish from sclerosing cholangitis and biliary/pancreatic malignancies. An accurate noninvasive test for diagnosis and monitoring of disease activity is lacking. We demonstrate that dominant IgG4+ B-cell receptor (BCR) clones determined by nextgeneration sequencing (NGS) accurately distinguish patients with IgG4-associated cholangitis/autoimmune pancreatitis (n=34) from those with primary sclerosing cholangitis (n=17) and biliary/pancreatic malignancies (n=17). A novel, more affordable, widely applicable quantitative polymerase chain reaction (qPCR) protocol analyzing the IgG4/IgG RNA-ratio in blood, also achieves excellent diagnostic accuracy (n=125). Moreover, this qPCR-test performed better than serum IgG4 levels in sensitivity (94% versus 86%) and specificity (99% versus 73%), and correlates with treatment response (n=20). Conclusion: IgG4+ BCR clones and IgG4/IgG RNA-ratiomarkedly improve delineation, early diagnosis and monitoring of IgG4-related disease of the biliary tree and pancreas.</p

High-throughput sequencing of human immunoglobulin variable regions with subtype identification

The humoral immune response plays a critical role in controlling infection, and the rapid adaptation to a broad range of pathogens depends on a highly diverse antibody repertoire. The advent of high-throughput sequencing technologies in the past decade has enabled insights into this immense diversity. However, not only the variable, but also the constant region of antibodies determines their in vivo activity. Antibody isotypes differ in effector functions and are thought to play a defining role in elicitation of immune responses, both in natural infection and in vaccination. We have developed an Illumina MiSeq high-throughput sequencing protocol that allows determination of the human IgG subtype alongside sequencing full-length antibody variable heavy chain regions. We thereby took advantage of the Illumina procedure containing two additional short reads as identifiers. By performing paired-end sequencing of the variable regions and customizing one of the identifier sequences to distinguish IgG subtypes, IgG transcripts with linked information of variable regions and IgG subtype can be retrieved. We applied our new method to the analysis of the IgG variable region repertoire from PBMC of an HIV-1 infected individual confirmed to have serum antibody reactivity to the Membrane Proximal External Region (MPER) of gp41. We found that IgG3 subtype frequencies in the memory B cell compartment increased after halted treatment and coincided with increased plasma antibody reactivity against the MPER domain. The sequencing strategy we developed is not restricted to analysis of IgG. It can be adopted for any Ig subtyping and beyond that for any research question where phasing of distant regions on the same amplicon is needed