Effectiveness of monovalent and pentavalent rotavirus vaccine.

OBJECTIVE: Previous US evaluations have not assessed monovalent rotavirus vaccine (RV1, a G1P[8] human rotavirus strain) effectiveness, because of its later introduction (2008). Using case-control methodology, we measured the vaccine effectiveness (VE) of the 2-dose RV1 and 3-dose pentavalent vaccine (RV5) series against rotavirus disease resulting in hospital emergency department or inpatient care. METHODS: Children were eligible for enrollment if they presented to 1 of 5 hospitals (3 in Georgia, 2 in Connecticut) with diarrhea of ≤10 days' duration during January through June 2010 or 2011, and were born after RV1 introduction. Stools were collected; immunization records were obtained from providers and state electronic immunization information system (IIS). Case-subjects (children testing rotavirus antigen-positive) were compared with 2 control groups: children testing rotavirus negative and children selected from IIS. RESULTS: Overall, 165 rotavirus-case subjects and 428 rotavirus-negative controls were enrolled. Using the rotavirus-negative controls, RV1 VE was 91% (95% confidence interval [CI] 80 to 95) and RV5 VE was 92% (CI 75 to 97) among children aged ≥8 months. The RV1 VE against G2P[4] disease was high (94%, CI 78 to 98), as was that against G1P[8] disease (89%, CI 70 to 96). RV1 effectiveness was sustained among children aged 12 through 23 months (VE 91%; CI 75 to 96). VE point estimates using IIS controls were similar to those using rotavirus-negative controls. CONCLUSIONS: RV1 and RV5 were both highly effective against severe rotavirus disease. RV1 conferred sustained protection during the first 2 years of life and demonstrated high effectiveness against G2P[4] (heterotypic) disease.

Parent understanding of the role of doctors and doctors in training on an inpatient pediatric ward.

BACKGROUND: Many physician trainees care for patients in an academic hospital. We studied parent understanding of the roles of medical students, interns, residents, and attending physicians in the inpatient setting of a children's hospital. DESCRIPTION: Surveys were given to parents during a hospital stay on a medical service asking about the responsibilities and education of physicians and trainees. EVALUATION: The majority of respondents knew that medical students were not doctors, could not write prescriptions, or supervise residents or attendings. Most respondents did not know that an intern had completed medical school, was a doctor, or could write prescriptions. Most respondents knew that attendings had graduated from medical school, were doctors, and supervise interns and students. Factors affecting understanding of these roles included the parent's level of education and race. CONCLUSION: Confusion exists about the different roles of physicians and trainees, particularly in parents without a college education, and who self-identify as non-White.

The effects of nonionic polymers on thyroid stimulation and TSH receptor binding by the human monoclonal TSH receptor autoantibody M22.

BACKGROUND: Nonionic polymers such as polyethylene glycol (PEG), polyvinyl alcohol (PVA), and dextran amplify the ability of thyroid stimulating antibodies (TSAbs) from patients with Graves' disease to stimulate cAMP production in thyroid cells. Therefore we sought to determine if nonionic polymers also augment the effects of the human thyroid stimulating monoclonal antibody (M22) on isolated thyroid cells. METHODS: The ability of nonionic polymers to alter the effects of M22 on certain parameters in porcine thyroid cells was examined. These parameters were augmentation of cAMP production (TSAb activity), inhibition of bovine thyrotropin (bTSH)-induced cAMP production (TBAb activity), and inhibition of bTSH binding to the TSH receptor (TSHR) (TBI activity). RESULTS: Stimulation of cAMP production by M22 in porcine thyroid cells was augmented by PEG, PVA, and dextran in a manner similar to that of Graves' serum. In contrast, TSH-stimulated cAMP production was not increased by nonionic polymers. M22-stimulated cAMP production was completely inhibited by the sera of patients with TBAb activity, and this inhibition was diminished by PEG. M22 and TBI activity in first and second generation assays and this activity was not affected by PEG. Binding of biotin-M22 to TSHR-coated plate wells (third generation assay) was not significantly increased by co-incubation with polymers. PEG augmented the binding of (125)I-M22 to TSHR-coated tubes by twofold, but this was associated with a threefold increase in nonspecific binding. There was no increase in total and nonspecific (125)I-TSH binding. This means that PEG has less than a twofold augmentative effect on (125)I-M22 binding to the TSHR. CONCLUSION: Nonionic polymers have similar effects in augmenting cAMP production in porcine thyroid cells in response to stimulation either by M22 or Graves' disease serum. The mechanism of this effect on the thyroid stimulating activity of M22 is unclear. The hypothesis that nonionic polymers augment M22 thyroid stimulation by increasing the mass of M22-occupied TSH receptors is not supported by the present study.

Estimation of serum TSH receptor autoantibody concentration and affinity.

We have used the human monoclonal TSH receptor (TSHR) autoantibody (M22) as a labeled ligand in competition with individual patient TSHR autoantibodies (TRAb) to estimate their serum concentrations and affinities. TSHR coated tubes, (125)I-labeled M22 IgG and Fab, and patient sera IgG and Fab were used in these studies. In 15 patients with Graves' disease, TRAb concentrations ranged from 50 to 500 ng/mL of serum (5- 60 parts per million of total serum IgG) and TRAb IgG affinities from 3.0 +/- 1.0-6.7 +/- 1.54-10(10) L/mol (mean +/- SD; n=3). Fab fragment affinities were similar to those of intact IgG. Serum TRAb with blocking (TSH antagonist; 4 patients) activity had similar affinities (3.0 +/- 0.25-7.2 +/- 2.2-10(10) L/mol) to TRAb IgG from patients with Graves' disease, but blocking TRAb concentrations were higher (1.7 - 27 mg/mL of serum). The concentrations of TRAb that we observed in the sera of the 15 Graves' patient (0.33 - 3.3 nmol/L) can be compared with that of circulating TSH. In particular, a serum TSH concentration of 100mU/L (0.7 nmol/L) is in the same range as the concentrations of TRAb we observed. Such a TSH concentration (similar to that observed after injection of 0.9 mg of recombinant human TSH) would be expected to cause a similar degree of thyrotoxicosis as seen in Graves' disease. Consequently, the thyroid-stimulating potencies (i.e., activity per mol) of patient serum TRAb and human TSH appear to be of a similar magnitude in vivo as well as in vitro. Overall, our results indicate that serum TRAb affinities are high and show only limited variations between different sera whereas concentrations of the autoantibodies vary widely.