Assessment of pasteurisation of milk and cream produced by on-farm dairies using a fluorimetric method for alkaline phosphatase activity

The alkaline phosphatase test is used as an indicator of adequate pasteurisation of milk and cream. A proprietary fluorimetric technique (Fluorophos) is a sensitive and quantitative method for the determination of alkaline phosphatase (ALP) activity in milk products. Currently, adequate pasteurisation of milk products is regarded as confirmed in samples that contain a residual bovine ALP activity of < or =500 mU/litre. This is equivalent to the statutory acceptable level of 4ug phenol/ml required by the EC analytical method. The purpose of the present study was to assess the effectiveness of pasteurisation of milk and cream produced by on-farm dairies. In a longitudinal study over a four-year period, 4,999 samples of milk and cream were collected from 130 on-farm dairies and from two large commercial dairies in NW England for comparison. Bovine ALP activity of >500 mU/litre was deemed as a failure and was found in 3.5% of whole milk, 2.4% semiskimmed milk, 5.0% of skimmed milk, and 39% of cream samples from on-farm dairies. Bovine ALP activity of >100 and <500 mU/litre was found in 18.4% of whole milk, 9.3% of semi-skimmed milk, 13.2% skimmed milk and 44.5% of cream samples from on-farm dairies. Results with skimmed milk samples showed significantly lower bovine ALP activity than whole milk. All 409 milk and cream samples from two large commercial dairies passed the fluorimetric test at less than 500 mU/litre of bovine ALP, and 99% of these milk and cream samples had bovine ALP activity of less than 100 mU/litre. The presence of residual bovine phosphatase indicates a failure and may be due to either inadequate pasteurisation or post pasteurisation contamination with raw milk. Residual bovine phosphatase was demonstrated in 108/114 (94.7%) of milk samples with a bovine ALP activity greater than 500 mU/litre, i.e. true failures. Of more concern is that residual bovine phosphatase was found in 395/401 (98.5%) of samples that gave bovine ALP activity greater than 100 mU/litre but equal to or less than 500 mU/litre. Residual bovine phosphatase was demonstrated in 37/108 (30.2%) of cream samples with bovine ALP activity greater than 500 mU/litre. Presence of reactivated bovine phosphatase is not an indication of a failure but can mask the presence of residual bovine phosphatase. Reactivated bovine phosphatase was found in 74/106 (69.8%) of cream samples. Our results confirm that the more sensitive fluorimetric method is suitable for testing pasteurised whole milk and semiskimmed milk, but for statutory purposes the acceptable level of residual bovine phosphatase should be <100 mU/litre. Our findings have highlighted a potential problem when testing skimmed milk and cream samples from on-farm dairies. To ensure public safety we need more stringent standards for the ALP test and new methods that will accurately confirm that pasteurisation of these products has been achieved.

Partial N-terminal sequences of larval cuticular proteins from the dipteran Ceratitis capitata

The partial amino acid sequences ranging in length over 17-30 residues from the N-terminus, have been obtained for nine cuticular proteins of Ceratitis capitata. Sequence similarities indicate that the proteins belong to a family which is related to cuticular proteins isolated from flexible cuticles of Drosophila melanogaster, Manduca sexta, Sarcophaga bullata and Hyalophora cecropia.

Glutamate-evoked release of adenosine and regulation of peripheral nociception

Glutamate (which facilitates peripheral nociception) releases adenosine (which inhibits peripheral nociception via adenosine A(1) receptors) when injected locally into the rat hindpaw. The present study determined whether this locally released adenosine could modulate spontaneous pain behaviors produced by a local injection of 1.5% formalin, by determining the effect of 8-cyclopentyl-theophylline (CPT; selective adenosine A(1) receptor antagonist) on flinching produced by formalin/glutamate combinations. Experiments were performed following a prior conditioning injection of 2.5% formalin into the contralateral hindpaw 3-4 days earlier. CPT augmented flinching behaviors produced by 1.5% formalin/1 micromol glutamate, but had no effect on behaviors produced by formalin or glutamate alone. CPT also augmented flinches generated by formalin/alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and formalin/kainic acid, but not by formalin/N-methyl-D-aspartate (NMDA) combinations. The conditioning leads to a clearer expression of the peripheral inhibitory effect of adenosine (inhibitory effect of an inhibitor of adenosine kinase on flinching also was observed), rather than an increased release of adenosine (no enhanced release observed by microdialysis). Microglia appear to be involved in the conditioning, as microglia are activated in the dorsal spinal cord 3 days following injection of 2.5% formalin, and augmentation of formalin/glutamate-induced flinching by CPT is inhibited by the glial metabolic inhibitor fluorocitrate. The augmentation of flinching by CPT is also eliminated following a spinal pretreatment with MK-801 (NMDA receptor antagonist), cyclohexyladenosine (adenosine A(1) receptor agonist), N(G)-nitro-L-arginine methyl ester HCl (nitric oxide synthetase inhibitor), and chelerythrine (protein kinase C inhibitor). The conditioning pretreatment with 2.5% formalin does not lead to a generalized chemical or thermal hypersensitivity in the contralateral hindpaw. This study demonstrates that prior exposure to 2.5% formalin in the contralateral hindpaw reveals an inhibitory effect of adenosine on peripheral nociception in the presence of glutamate; this conditioning involves microglia and other mechanisms involved in central sensitization.

Differential activation on fMRI of monozygotic twins discordant for AD

This is the first report of fMRI in monozygotic twins discordant for AD. FMRI brain activation patterns were examined during visuospatial and verbal working memory tasks. The affected twin had greater parietal involvement bilaterally during both working memory tasks and reduced left dorsolateral prefrontal cortex activity on the visuospatial memory task. Thus, fMRI may identify additional brain regions recruited in patients with AD to perform a given cognitive task.

Short-term temporal variation in PM2.5 mass and chemical composition during the Atlanta Supersite Experiment, 1999

Measurements in urban Atlanta of transient aerosol events in which PM2.5 mass concentrations rapidly rise and fall over a period of 3-6 hr are reported. The data are based on new measurement techniques demonstrated at the U.S. Environmental Protection Agency (EPA) Atlanta Supersite Experiment in August 1999. These independent instruments for aerosol chemical speciation of NO3-, SO4(2-), NH4+, and organic and elemental carbon (OC and EC), reconstructed the observed hourly dry PM2.5 mass to within 20% or better. Data from the experiment indicated that transient PM2.5 events were ubiquitous in Atlanta and were typically characterized by a sudden increase of EC (soot) and OC in the early morning or SO4(2-) in the late afternoon. The frequent temporal decoupling of these events provides insights into their origins, suggesting mobile sources in metro Atlanta as the main contributor to early morning PM2.5 and more regionally located point SO2 sources for afternoon PM2.5 events. The transient events may also have health implications. New data suggest that short-term PM2.5 exposures may lead to adverse health effects. Standard integrated filter-based techniques used in PM2.5 compliance monitoring networks and in most past PM2.5 epidemiologic studies collect samples over 24-hr periods and thus are unable to capture these transient events. Moreover, health-effects studies that focus on daily PM2.5 mass alone cannot evaluate the health implications of the unique and variable chemical properties of these episodes.

Oscillating on borrowed time: diffusible signals from immortalized suprachiasmatic nucleus cells regulate circadian rhythmicity in cultured fibroblasts

The capacity to generate circadian rhythms endogenously and to confer this rhythmicity to other cells was compared in immortalized cells derived from the suprachiasmatic nucleus (SCN) and a fibroblast line to differentiate SCN pacemaker properties from the oscillatory behavior of non-clock tissues. Only SCN2.2 cells were capable of endogenously generating circadian rhythms in 2-deoxyglucose uptake and Per gene expression. Similar to SCN function in vivo, SCN2.2 cells imposed rhythms of metabolic activity and Per gene expression on cocultured NIH/3T3 fibroblasts via a diffusible signal. The conferred rhythms in NIH/3T3 cells were phase delayed by 4-12 hr relative to SCN2.2 circadian patterns, thus resembling the phase relationship between SCN and peripheral tissue rhythms in vivo. Sustained metabolic rhythmicity in NIH/3T3 cells was dependent on continued exposure to SCN2.2-specific outputs. In response to a serum shock the NIH/3T3 fibroblasts exhibited recurrent oscillations in clock gene expression, but not in metabolic activity. These molecular rhythms in serum-shocked fibroblasts cycled in a phase relationship similar to that observed in the SCN in vivo; peak Per1 and Per2 mRNA expression preceded the rhythmic maxima in Cry1 and Cry2 mRNA levels by 4 hr. Despite these clock gene oscillations the serum-shocked NIH/3T3 cells failed to drive circadian rhythms of Per1 and Per2 expression in cocultures of untreated fibroblasts, suggesting that expression and circadian regulation of the Per and Cry genes are not sufficient to confer pacemaker function. Therefore, SCN-specific outputs are necessary to drive circadian rhythms of metabolic activity, and these output signals are not a direct product of clock gene oscillations.

Face processing occurs outside the fusiform 'face area' in autism: evidence from functional MRI

Processing the human face is at the focal point of most social interactions, yet this simple perceptual task is difficult for individuals with autism, a population that spends limited amounts of time engaged in face-to-face eye contact or social interactions in general. Thus, the study of face processing in autism is not only important because it may be integral to understanding the social deficits of this disorder, but also, because it provides a unique opportunity to study experiential factors related to the functional specialization of normal face processing. In short, autism may be one of the only disorders where affected individuals spend reduced amounts of time engaged in face processing from birth. Using functional MRI, haemodynamic responses during a face perception task were compared between adults with autism and normal control subjects. Four regions of interest (ROIs), the fusiform gyrus (FG), inferior temporal gyrus, middle temporal gyrus and amygdala were manually traced on non-spatially normalized images and the percentage ROI active was calculated for each subject. Analyses in Talairach space were also performed. Overall results revealed either abnormally weak or no activation in FG in autistic patients, as well as significantly reduced activation in the inferior occipital gyrus, superior temporal sulcus and amygdala. Anatomical abnormalities, in contrast, were present only in the amygdala in autistic patients, whose mean volume was significantly reduced as compared with normals. Reaction time and accuracy measures were not different between groups. Thus, while autistic subjects could perform the face perception task, none of the regions supporting face processing in normals were found to be significantly active in the autistic subjects. Instead, in every autistic patient, faces maximally activated aberrant and individual-specific neural sites (e.g. frontal cortex, primary visual cortex, etc.), which was in contrast to the 100% consistency of maximal activation within the traditional fusiform face area (FFA) for every normal subject. It appears that, as compared with normal individuals, autistic individuals 'see' faces utilizing different neural systems, with each patient doing so via a unique neural circuitry. Such a pattern of individual-specific, scattered activation seen in autistic patients in contrast to the highly consistent FG activation seen in normals, suggests that experiential factors do indeed play a role in the normal development of the FFA.

Face processing occurs outside the fusiform 'face area' in autism: evidence from functional MRI

Processing the human face is at the focal point of most social interactions, yet this simple perceptual task is difficult for individuals with autism, a population that spends limited amounts of time engaged in face-to-face eye contact or social interactions in general. Thus, the study of face processing in autism is not only important because it may be integral to understanding the social deficits of this disorder, but also, because it provides a unique opportunity to study experiential factors related to the functional specialization of normal face processing. In short, autism may be one of the only disorders where affected individuals spend reduced amounts of time engaged in face processing from birth. Using functional MRI, haemodynamic responses during a face perception task were compared between adults with autism and normal control subjects. Four regions of interest (ROIs), the fusiform gyrus (FG), inferior temporal gyrus, middle temporal gyrus and amygdala were manually traced on non-spatially normalized images and the percentage ROI active was calculated for each subject. Analyses in Talairach space were also performed. Overall results revealed either abnormally weak or no activation in FG in autistic patients, as well as significantly reduced activation in the inferior occipital gyrus, superior temporal sulcus and amygdala. Anatomical abnormalities, in contrast, were present only in the amygdala in autistic patients, whose mean volume was significantly reduced as compared with normals. Reaction time and accuracy measures were not different between groups. Thus, while autistic subjects could perform the face perception task, none of the regions supporting face processing in normals were found to be significantly active in the autistic subjects. Instead, in every autistic patient, faces maximally activated aberrant and individual-specific neural sites (e.g. frontal cortex, primary visual cortex, etc.), which was in contrast to the 100% consistency of maximal activation within the traditional fusiform face area (FFA) for every normal subject. It appears that, as compared with normal individuals, autistic individuals 'see' faces utilizing different neural systems, with each patient doing so via a unique neural circuitry. Such a pattern of individual-specific, scattered activation seen in autistic patients in contrast to the highly consistent FG activation seen in normals, suggests that experiential factors do indeed play a role in the normal development of the FFA.

Atypical patterns of cerebral motor activation in autism: a functional magnetic resonance study

BACKGROUND

Early neurodevelopmental pathogenesis in autism potentially affects emerging functional maps, but little imaging evidence is available.

METHODS

We studied eight male autistic and eight matched normal subjects, using functional magnetic resonance imaging during visually paced finger movement, compared to a control condition (visual stimulation in the absence of motor response).

RESULTS

Groupwise analyses showed activation in contralateral perirolandic cortex, basal ganglia, and thalamus, bilateral supplementary motor area, and ipsilateral cerebellum for both groups. However, activations were less pronounced in the autism group. Direct group comparisons demonstrated greater activation in perirolandic and supplementary motor areas in the control group and greater activation (or reduced deactivation) in posterior and prefrontal cortices in the autism group. Intraindividual analyses further showed that strongest activations were consistently located along the contralateral central sulcus in control subjects but occurred in locations differing from individual to individual in the autism group.

CONCLUSIONS

Our findings, though based on a rather small sample, suggest abnormal individual variability of functional maps and less distinct regional activation/deactivation patterns in autism. The observations may relate to known motor impairments in autism and are compatible with the general hypothesis of disturbances of functional differentiation in the autistic cerebrum.

Attention function and dysfunction in autism

Impairments of attention are among the most consistently reported cognitive deficits in autism, and they continue to be a key focus of research. This is in no doubt due to the importance of normal attention function to the development of many so-called "higher level" cognitive operations, and to the likely involvement of attention dysfunction in certain clinical features of autism. Autistic individuals display a wide range of attentional abilities and deficits across the many domains of attention function, including selective, sustained, spatial, and shifting attention operations. This unique pattern of attention function and dysfunction has profound implications for the development and treatment of autistic children. The present review will explore this pattern of attentional strengths and weaknesses and the neural defects that underlie them.

Echocardiographic texture analysis using the wavelet transform: differentiation of early heart muscle disease

Echocardiographic quantitation of myocardial texture for diagnosis of early cardiomyopathy (CMP) remains problematic. Conventional statistical methods are limited, contributed by a small image region-of-interest (ROI) and difficulty in discrimination from noise. This study was performed to evaluate the 2-D Haar wavelet decomposition method as a tool to identify textural changes in a rat model of early CMP, focusing on changes that occur before development of M-mode structural abnormalities. Early diabetic CMP, ethanol CMP and diabetic-ethanol CMP rat models were evaluated. Echocardiography was performed on two groups of rats. Group I (5 week cohort, n = 4 per subgroup) included controls, rats on 12% ethanol, a diabetic subgroup, and diabetic rats on 4% ethanol. Group II (10 week cohort, n = 5 per subgroup) included the same categories as group I with an additional subgroup taking 4% ethanol was also studied. M-mode left ventricular measurements were comparable in all subgroups of group I. However, diabetic rats in group II had an increased left ventricular dimension (LVD) compared to all others and an increased septal dimension (IVSD) and posterior wall dimension (PWD) were noted in the 4% and 12% ethanol groups. End-diastolic digital images of all rats in the parasternal short axis view, at the papillary muscle level, were downloaded to a computer. A 16 x 16 (ROI) was selected from the anterior interventricular septum. Although standard statistical methods could not differentiate any of the groups, calculation of textural energy and normalized textural energy with the 2-D Haar wavelet decomposition method found at 5 weeks increased normalized texture energy in diabetics compared to all others. At 10 weeks increased texture energy was noted in diabetics. Diabetic-ethanol rats at both 5 and 10 weeks revealed a blunted textural energy compared to diabetic rats. In a rat model of diabetic cardiomyopathy, the 2-D wavelet decomposition method identified textural energy changes before development of echocardiographic structural changes. Ethanol-associated blunting of textural changes in diabetic rats was also noted. This method for quantitation of ventricular texture may be relevant for diagnosis of early cardiomyopathy.

Feelings of knowing in the Ranschburg effect

In two experiments, we assessed feelings of knowing (FOKs) for the Ranschburg effect to examine the types of retrieval ease that affect FOKs. In the Ranschburg effect, retrieval performance for repeated items differs from nonrepeated items in supramemory span tasks. We found that FOKs are affected by memory manipulations that affect recall processes, but not by manipulations that affect recognition. This suggests that processes that affect recognition, such as target familiarity, do not affect FOKs, whereas processes that affect recall, such as response suppression and guessing factors, affect FOKs. We propose that an integrated theory of FOKs must include mechanisms responsive to both encoding and retrieval factors (such as retrieval accessibility and cue familiarity), which are highly susceptible to output interference.