Determination of plasma theophylline by straight-phase high-performance liquid chromatography: Elimination of interfering caffeine metabolites

Several authors have recently reported interference in theophylline analysis by paraxanthine (1,7-dimethylxanthine), an important metabolite of caffeine. A method for the determination of theophylline in plasma is described, eliminating caffeine and related compounds by means of straight-phase high-performance liquid chromatography. The resulting procedure is sufficiently rapid, accurate and sensitive to be applied in routine monitoring of therapeutic levels in patients as well as for pharmacokinetic purposes. Although only 0.1 ml of sample is required, concentrations as low as 0.2 mg/l can be measured with acceptable precision. A brief comparative evaluation of this procedure with a radioimmunoassay is made.     

Chick embryo fibroblasts produce two forms of hyaluronidase

Cultured chick embryo fibroblasts derived from skin and skeletal muscle exhibit hyaluronidase activity both associated with the cell layer and secreted into the medium. Although both forms of the enzyme have a number of similar characteristics (R.W. Orkin and B.P. Toole, 1980, J. Biol. CHem. 255), they differ in thermal stability at neutral pH and in behavior on ion-exchange chromatography. Both forms of the enzyme are equally stable at acidic pH for long intervals, but the cell-associated hyaluronidase is significantly less stable than the secreted froms at neutral pH and at temperatures more than or equal to 30 degrees C. Neither the presence of proteases nor inhibitors of hyaluronidase appear to be involved in the cell-asspcoated enzyme. Chromatography of the two forms of hyaluronidase on carboxymethyl cellulose reveals that most (60-90 percent) of the secreted form of the enzyme elutes at a lower ionic strength than the cell- associated enzyme. Treatment of the secreted form of hyaluronidase with neuraminidase shifts its elution profile on carboxymethyl cellulose toward that of the cell-associated form, and also decreases its thermal stability at neutral pH. In contrast, treatment of the secreted form of hyaluronidase with alkaline phosphatase has no detectable effect. These data suggest that the secreted hyaluronidase differs from the cellular form in possessing additional sialic acid residues which endow the former with increased stability in the extracellular milieu.     

Rethinking the life sciences

The life sciences are at loggerheads with society and neither much trusts the other. To unleash the full potential of molecular life science, a new contract with society and more organized ways of doing research are needed.Suppose that an international group of scientists presents a 15-year, €750 million research programme to unravel the molecular mechanisms of metabolic syndrome, a disorder implicated in obesity, type 2 diabetes, cardiovascular diseases, cancer and other diseases. The results from this project will neither replace obvious preventive measures—such as reducing food intake or increasing exercise—nor will it magically generate pharmaceutical treatments. Instead, the research aims to gain a systems-level understanding of metabolic syndrome that could lead to more effective prevention schemes, improved food quality, improved early diagnosis of people with higher risk, and better therapies and drugs. From an economic point of view, this is an excellent investment, as the costs of obesity and its co-morbidities in the European Union are estimated to increase to €100 billion per year in 2030 [1]. If the proposed research project helped to lower the costs by only 10%, it would generate a considerable return on investment.Sadly, such a project would be unlikely to receive funding. The reason is not because it would be scientifically unrealistic or unfeasible, or because society does not want to support expensive research programmes. The Manhattan Project to develop the atomic bomb, the Large Hadron Collider at CERN to identify the Higgs boson and the European Southern Observatory in Chile are all examples of large-scale research programmes that are publicly funded. Rather, the life sciences suffer from a unique set of problems that have developed in the past decades and would prevent such a project receiving popular support and funding. This article explores why this is the case and how modern life sciences could contribute more to society. Specifically, we argue that two areas need rethinking: the embedding of the life sciences in society and the way that research is organized.There are more than seven billion humans on this planet who need food, energy and health care, and life science research has a huge potential to address these needs. However, critics point out that many of the promises made by life scientists in the past have still not materialized. One example is the promises made to justify the US $3 billion spent on the Human Genome Project. It was supposed to provide a ‘blueprint of life'' that would quickly lead to new approaches for curing diseases. In the end, however, despite its success at generating new research fields and knowledge, the Human Genome Project has not (yet) lived up to its promises.…critics point out that many of the promises made by life scientists in the past have still not materializedWorse still, some critics perceive the life sciences as a problem that is creating physical and moral hazards. Rather than writing a blank cheque to allow scientists to pursue their research goals, governments are increasingly demanding control over the direction and application of research. This approach tends to reward short-term applications of scientific resources to help solve societal problems. Moreover, the success of projects has to be demonstrated at the application stage, before any of the research has even begun, which is fundamentally incompatible with the trial-and-error processes at the heart of creative research. Long-term, in-depth investments in research have become unpopular. Ironically, this ‘short-termism'' undermines the potential of the life sciences to be realized. Life sciences and society seem to be in a dead-lock.The life sciences must therefore regain the trust of society. This cannot be done merely by emphasizing academic freedom and the autonomy of science, or by promoting the so-called ‘cornucopia'' of science and technology, implying that both bring only precious gifts. It is also not useful to suggest that morals should follow scientific and technological developments rather than shape them. It is equally counterproductive when scientists deny taking responsibility for how their findings are applied after they leave the laboratory. As Ravetz [2] famously remarked: “Scientists claim credit for penicillin, while Society takes the blame for the Bomb”. In reality, the definition of ends is always influenced by the available means.One approach to restore the trust between the life sciences and society is to create platforms that allow for open and symmetrical dialogue. Fortunately, we do not have to start from scratch, as the recent discussions about responsible research and innovation (RRI; [3,4,5]) have already begun this process. According to René von Schomberg, policy officer at the European Commission, Directorate-General for Research, RRI is “a transparent, interactive process by which societal actors and innovators become mutually responsive to each other with a view to the (ethical) acceptability, sustainability and societal desirability of the innovation process and its marketable products” [5]. An example is the EU ‘Code of conduct for responsible nanosciences and nanotechnologies research''. The concept is also expected to have a major role in the upcoming EU Framework Programme for Research and Innovation ‘Horizon 2020'', and national research councils in the UK, Norway and the Netherlands are supporting initiatives under this heading. The National Nanotechnology Initiative in the USA heralds ‘responsible development'', and the Presidential Commission on the Study of Bioethical Issues recommends ‘responsible stewardship'' and ‘prudent vigilance'' in relation to synthetic biology.…‘short-termism'' undermines the potential of the life sciences to be realizedThe starting point of RRI is that society, science, technology and morality comprise a single system. If one component changes, the others are also affected. The traditional division of labour—science provides knowledge and instruments, whilst society determines values and application—therefore does not work anymore. Life scientists have to acknowledge and accept that society is co-shaping their agenda. Scientists should also realise that vice versa they co-shape society, rather than just offering knowledge and tools. In other words, science and society co-evolve [6]. Bringing life sciences and society closer together requires the concerted efforts of life scientists, social scientists, ethicists, legal experts, economists, policy-makers, market parties and laypeople.Research and technology are rational activities at the micro level. Science is superior to other methods for creating reliable, testable knowledge, and technology is unmatched in providing solutions to many problems. But both tend to become irrational at higher levels of organization—we drive highly sophisticated cars and still get stuck in traffic jams, nuclear waste remains a huge problem for generations to come, and knowledge and technology have enabled increasingly lethal weaponry. Science and technology therefore need moral guidelines—such as ‘the precautionary principle''—to direct what kind of knowledge is worth pursuing and should be applied, why and for whom. This is a one-sided view, however, that ignores the perspective of the scientific method. As science proceeds by trial and error, it must be fundamentally open to pursue any avenue of knowledge. As such, new scientific insight and technological opportunities can often necessitate a reappraisal of established morals. Keeping science, technology and morality in contact with each other requires more than rules and prohibitions that can be ticked off on a form. It needs a culture of attentiveness and reflection to avoid tunnel vision whilst allowing flexibility and improvisation to learn from mistakes and change course if needed.During the past two decades, many experiments in public understanding, awareness and participation in science and technology have been conducted. In the Netherlands, for instance, this has included science cafes, citizen panels [7], nation-wide public debates about nuclear energy [8], biotechnology and food in 2001 [9], and public participation (http://www.nanopodium.nl). It is yet to be determined how effective these efforts have been. Appreciating that science and technology, as well as society and morality, constitute parts of a larger system demands skills, institutions and procedures that have not as yet been adequately developed. Indeed, many scientists continue to adhere to a ‘knowledge deficit'' model of public outreach that has scientists ‘explaining'' scientific developments to an audience that is perceived to be ignorant at best and technophobic at worst. On the other hand, NGOs have sometimes hijacked discussions by simply being ‘against'', rather than contributing to the debate in an open and constructive manner. Another problem is that the life sciences are poorly organized. They lack an organization that represents the community and can professionalize the relationship between society and life sciences.What are the requirements for developing responsibly the relationship between society and the life sciences? First, it is important that scientists are explicit about the trial-and-error character of research, and are honest and transparent about the results they expect, rather than inducing unrealistic expectations. Laypeople should be made aware of how the life sciences function and what they might achieve. It is also important that citizens understand that science produces theories that can be corroborated to some degree rather than absolute certainties, and that technology offers solutions that can do both more or less than expected. This should also make clear that the distinction between fundamental science and applied technology is both real and illusionary. It is real because it is important to allow space for unfettered curiosity. It is illusionary because even the most ‘fundamental'' research is usually embedded in a general normative vision about its possible use. Moreover, even truly applied research can generate new fundamental insight.Second, it is important to engage societal actors as early as possible in the research enterprise, so that they can determine the research agenda rather than be confronted with final results and products. A specific suggestion would be to attach a ‘layman advisory board'' to large research programmes. Although the tasks of such boards should be defined carefully to avoid tying them up in minutiae, such boards can help to enhance the involvement of society in the life sciences. Engaging interested individuals and stakeholders early on in the process and offering them an opportunity to influence the research agenda would help to foster a constructive attitude.These boards should put the definitions, visions and goals of scientific research to the social test and set research priorities accordingly. Research is inevitably conducted with reference to priorities—such as advancing knowledge, improving public health, economic development and military use—but setting these priorities exceeds the authority of science. We need social scientists, philosophers, lawyers, policy-makers, politicians, companies, opinion-makers, NGOs and patient organizations to discuss with life scientists how scientific results can be developed to benefit society. For example, because knowledge can be viewed as an economically valuable resource, we have to consider whether intellectual property laws are adequate to deal with new forms of knowledge. The ongoing debate about the legal and moral problems of intellectual property [10] also highlights issues of fairness and justice. How will science and technology influence prevailing ideas about the meaning of a ‘healthy life''? How much do we value physical and mental health, how much are we willing to invest in this value, and how will society react to choices made by individuals? The life sciences are creating enormous data collections about individuals, which raises issues about access, privacy, ownership and consent. Discussing these issues would neither put the life sciences in a strait jacket nor would it curtail curiosity-driven research. On the contrary, we should be more worried about the current situation, in which governments set the agenda by choosing which areas are funded without consulting the life sciences community or other stakeholders.The sequencing of the human genome and the rapid development of new technologies and research fields—genomics, proteomics, advanced light microscopy, bioinformatics, systems biology and synthetic biology—have not yet paid off in terms of highly visible applications that provide a significant benefit to society. However, there are many examples of progress both scientifically and clinically, such as the ongoing Encyclopaedia of DNA Elements project (ENCODE; http://encodeproject.org), the stratification of patients for anti-cancer therapies based on molecular markers or the creation of genetically modified disease-resistant plants. Notwithstanding, applying the new technologies made scientists realize that biological systems are much more complex than anticipated. The multi-layered and multi-scale complexity of cells, organisms and ecosystems is a huge challenge for research in terms of generating, analysing and integrating enormous amounts of data to gain a better understanding of living systems at all levels of organization.However, and remarkably, the life sciences have not adapted accordingly to tackle bigger challenges with larger teams comparable with their colleagues in physics and astronomy. Most research is still carried out by small groups or collaborations that are woefully inadequate to address the full complexity of living systems. This type of research is grounded in the history of molecular biology when scientists focused on individual genes, proteins and metabolic pathways. Scientists hope that many small discoveries and advances made by many individual research groups will eventually add up to a more complete picture, an approach that clearly does not work and must change. The new challenge is to systematically acquire and integrate comprehensive data sets on the huge number of components at the cellular level and that of tissues, organs and complete organisms. This requires the life sciences to scale up their research efforts into larger projects.The putative research programme described at the beginning of this paper could help to reduce the health and economic burden of metabolic syndrome. This multifactorial disorder is an excellent example of the complex interplay between organs, tissues, cells, molecules, lifestyle, genetic factors, age and stress. Unravelling this daunting but finite complexity requires a major and well-coordinated effort. It would have to combine diverse skills and disciplines, including biology, chemistry, medicine, mathematics, physics and engineering. Similar considerations are true for research into areas such as cancer, Alzheimer disease or the development of efficient biofuels. Why, then, are we not making the necessary investments? The answer to this question has four components that we address below: scaling and management of research programmes, the academic culture and funding.First, one could argue that many national and European research programmes already focus on many aspects of metabolic syndrome. Together, they probably represent an investment of several hundred million Euros. So why spend another €750 million? The problem is that the results from individual research efforts simply do not add up due to a lack of standardization in regard to experiments, the use of model systems and protocols. Given the complexity of the disease, defining standard operation protocols (SOPs) is not a trivial task and requires a considerable research effort. However, experience shows that developing SOPs should be an integral part of larger research programmes. Moreover, SOPs change as our knowledge increases. SOPs can only be effective and stimulate research in the context of a sufficiently large and receptive research community, dedicated to a common well-defined research goal. An example of the successful development and implementation of SOPs in a ‘learning-by-doing'' setting is the German Virtual Liver Network (VLN) programme (http://www.virtual-liver.de). Obviously, a considerable fraction of the €750 million should come from regrouping and readjusting existing research in the field of metabolic syndrome.Second, we have remarkably little experience in managing concerted large-scale research efforts in the life sciences in the range of €100–1,000 million. The Human Genome Project cost US $3 billion. However, genomes are just DNA sequences, and it is relatively easy to define SOPs and integrate the contributions of many research groups. In terms of research management it was relatively straightforward compared with, for instance, a metabolic syndrome programme, which would have many more dimensions and components. It would require a highly coordinated approach, as the experiments of the participating research groups from different institutes and countries are strongly interdependent and the results must add up to a larger picture.To keep such a complex research programme on track, on time and within budget, strategic decisions will inevitably need to be made at a central level, rather than by individual researchers. A serious risk is that scaling-up coordinated research efforts will result in excessive bureaucracy and inflexibility that could kill creativity. Avoiding this problem is a major challenge. The life sciences could learn here from large, long-term projects in other fields, such as high-energy physics, astronomy and ecology. An instructive example is the Census of Marine Life programme [11] that successfully measured the diversity, distribution and abundance of marine life in the oceans over ten years. It involved 80 countries and 640 institutions and had a budget of US $650 million [12]. A recent overview and analysis of large-scale research efforts in the life sciences has been presented and discussed in [13,14,15].A third aspect is academic culture, which cherishes freedom, independence and competition and will not necessarily mesh well with the idea of large, tightly managed research programmes. Even so, research institutions will probably compete to participate in goal-oriented, large-scale research programmes. In fact, this is largely similar to the way most research is funded presently, for instance, through the Framework Programmes of the European Commission, except that the total collective effort is scaled up by one to two orders of magnitude. Moreover, as large-scale efforts involve longer timescales of between 10 and 15 years, it would offer a more stable basis of financing research. However, as the cooperation between parties and their interdependency will need to increase, participating research institutes and consortia will be held much more accountable for their contribution to the overall goals. ‘Take-the-money-and-run'' is no longer an option. This will obviously require explicit agreements between a programme director and participating institutions.In addition, academic institutions should rethink their criteria for selecting and promoting researchers. The impact factor, h-factor and citation scores [16] will have to be abandoned or modified as large-scale research efforts with an increasing number of multi-author publications will decrease their ability to assess individuals. Consequently, less emphasis will be put on first or last authorships, whilst project and team management skills might become more relevant.Academic freedom and creativity will be just as essential to a collective research enterprise as it is to small projects and collaborations. Large-scale research programmes will create new scientific questions and challenges, but they will not tell investigators how to address these. Academics will be free to choose how to proceed within the programme. Moreover, researchers will benefit from tapping into well-structured, large, knowledge bases, and they will have early access to the relevant data of others. Hence, being part of a large, well-organized research community brings benefits that might compensate for a perceived decrease in independence. Again, all of this depends strongly on how a large-scale programme is organized and managed, including the distribution of responsibilities, data-sharing policies and exchanges of expertise. Competition will probably remain part of the scientific endeavour, but it is important that it does not hamper collaboration and data sharing.Whilst we stress the need for larger-scale research efforts in the life sciences to have an impact on society, we also want to acknowledge the crucial role of classical curiosity-driven research programmes. It is essential to develop a reasonable and effective balance between different types of research in life sciences.A fourth issue is the lack of adequate funding mechanisms for international, large-scale research efforts. Given the ambiguous relationship between the life sciences and society—as argued in the first part of this essay—this problem can only be solved if life scientists convince policy-makers, funders and politicians that research can significantly contribute to solving societal problems and at reasonable costs. If not, life sciences will not flourish and society will not profit. As argued above, research efforts should be scaled to the complexity of the systems they intend to investigate. There are only a few problem-focused research programmes with a volume of more than €50 million. The VLN, funded to the tune of €43 million over five years by the German ministry for education and research, comes close. Its aim is to deliver a multi-scale representation of liver physiology, integrating data from the molecular, cellular and organ levels. The VLN involves 69 principal investigators dispersed throughout Germany and is headed by a director who is responsible for keeping the programme on track and on time. Issues such as standardization, division of responsibilities between the director and principal investigators, and decision-making procedures are tackled as the programme develops.If it is possible to rekindle the trust between society and the life sciences, will society be more willing to fund expensive, large-scale research programmes? Previous examples of publicly funded scientific and technological programmes in the multi-billion Euro range are the Large Hadron Collider, the Apollo programme and the Human Genome Project. Amazingly, none of these contributed directly to human well-being, although the Human Genome Project did make such promises. Hence, a life science programme that targets a crucial societal problem convincingly, such as metabolic syndrome, should have a fair chance of being acceptable and fundable.The above four issues must be addressed before the life sciences can successfully tackle major societal problems. It will need action from the research community itself, which is painfully lacking an organization to speak on behalf of life scientists and that can take the lead in discussions, internally and between society and science. Any such organization could learn from other areas, such as high-energy physics (CERN), astronomy (European Southern Observatory) and space research (European Space Agency). It would be tremendously helpful if a group of life scientists would get this issue on the agenda. This paper is meant to stimulate that process.In summary, we argue that if society wants to benefit from what the modern life sciences have to offer, we must act on two parallel tracks. One is to bring the life sciences closer to society and accept that society, science and morality are inseparable. The other is to rethink how we organize research in the life sciences. Both tracks create major challenges that can only be tackled successfully if the life sciences get organized and create a body that can lead the debate. At a more fundamental level, we need to decide what type of knowledge we want to acquire and why. Clearly, the value of generating knowledge for the sake of knowledge itself is important, but it must constantly be balanced with the values of society, which requires a dialogue between researchers and society.? Open in a separate windowTsjalling SwierstraOpen in a separate windowNiki VermeulenOpen in a separate windowJohan BraeckmanOpen in a separate windowRoel van Driel     

Intense photon emission induced by fracture of γ–irradiated Dy‐, Tm‐, Sm‐ and Mn‐doped CaSO4 single crystals

When an γ‐irradiated Dy‐, Tm‐, Sm‐ or Mn‐doped CaSO₄ crystal is impulsively deformed, two peaks appear in the ML intensity versus time curve, whereby the first ML peak is found in the deformation region and the second in the post‐deformation region of the crystals. In this study, intensities I_m1 and I_m2 corresponding to first and second ML peaks, respectively, increased linearly with an impact velocity v₀ of the piston used to deform the crystals, and times t_m1 and t_m2 corresponding to the first and second ML peaks, respectively, decreased with impact velocity. Total ML intensity initially increased with impact velocity and then reached a saturation value for higher values of impact velocity. ML intensity increased with increasing γ‐doses and size of crystals. Results showed that the electric field produced as a result of charging of newly‐created surfaces caused tunneling of electrons to the valence band of the hole‐trapping centres. The free holes generated moved in the valence band and their subsequent recombination with electron trapping centres released energy, thereby resulting in excitation of luminescent centres. Copyright © 2012 John Wiley & Sons, Ltd.     

Cadmium pathology in an insect cell line: ultrastructural and biochemical effects

Cadmium (Cd) pathology was studied in an insect cell line (Aedes albopictusC6/36) at the ultrastructural level. The most prominent pathological changes occurred at the level of the nucleus: chromatin clumping, indentations, filling and dilatation of the perinuclear cisternae and an increased amount of bound ribosomes were observed. In the cytoplasm, condensation and swelling of mitochondria, increase of both free and membrane-bound ribosomes, filling and dilatation of the rough endoplasmic reticulum, and increase of the lysosomal system were the most conspicuous effects. The increased content of the perinuclear and cytoplasmic cisternae was probably due to an increased protein synthesis or a disturbance of the protein export system. This picture differed clearly from the osmotically swollen electron-lucent cisternae that have been described in other pathological situations. The enhancement of the lysosomal system was paralleled by a slight but significant stimulation of the acid phosphatase activity in the sublethal Cd concentration range. In vitro experiments suggested that Cd probably acts directly on this enzyme. Abnormal medium acidification in cultures treated with low Cd levels was correlated with an increased production of lactic acid. Together with the morphological data, this suggested a Cd-induced impairment of the aerobic metabolism.     

Assessing metabolic activity in aging Caenorhabditis elegans: concepts and controversies

It is widely believed that normal by-products of oxidative metabolism and the subsequent molecular damage inflicted by them couple the aging process to metabolic rate. Accordingly, high metabolic rates would be expected to accelerate aging, and life-extending interventions are often assumed to act by attenuating metabolic rate. Notorious examples in Caenorhabditis elegans are food restriction, mutation in the Clock genes and several genes of the insulin-like signalling pathway. Here we discuss how metabolic rate can be accurately measured and normalized, and how to deal with differences in body size. These issues are illustrated using experimental data of the long-lived mutant strains clk-1(e2519) and daf-2(e1370). Appropriate analysis shows that metabolic rates in wildtype and in the clk-1 mutant are very similar. In contrast, the metabolic rate profiles point to a metabolic shift toward enhanced efficiency of oxidative phosphorylation in the daf-2 worms.     

The Link between Microbial Diversity and Nitrogen Cycling in Marine Sediments Is Modulated by Macrofaunal Bioturbation

Objectives

The marine benthic nitrogen cycle is affected by both the presence and activity of macrofauna and the diversity of N-cycling microbes. However, integrated research simultaneously investigating macrofauna, microbes and N-cycling is lacking. We investigated spatio-temporal patterns in microbial community composition and diversity, macrofaunal abundance and their sediment reworking activity, and N-cycling in seven subtidal stations in the Southern North Sea.

Spatio-Temporal Patterns of the Microbial Communities

Our results indicated that bacteria (total and β-AOB) showed more spatio-temporal variation than archaea (total and AOA) as sedimentation of organic matter and the subsequent changes in the environment had a stronger impact on their community composition and diversity indices in our study area. However, spatio-temporal patterns of total bacterial and β-AOB communities were different and related to the availability of ammonium for the autotrophic β-AOB. Highest bacterial richness and diversity were observed in June at the timing of the phytoplankton bloom deposition, while richness of β-AOB as well as AOA peaked in September. Total archaeal community showed no temporal variation in diversity indices.

Macrofauna, Microbes and the Benthic N-Cycle

Distance based linear models revealed that, independent from the effect of grain size and the quality and quantity of sediment organic matter, nitrification and N-mineralization were affected by respectively the diversity of metabolically active β-AOB and AOA, and the total bacteria, near the sediment-water interface. Separate models demonstrated a significant and independent effect of macrofaunal activities on community composition and richness of total bacteria, and diversity indices of metabolically active AOA. Diversity of β-AOB was significantly affected by macrofaunal abundance. Our results support the link between microbial biodiversity and ecosystem functioning in marine sediments, and provided broad correlative support for the hypothesis that this relationship is modulated by macrofaunal activity. We hypothesized that the latter effect can be explained by their bioturbating and bio-irrigating activities, increasing the spatial complexity of the biogeochemical environment.     

An overview of malaria transmission from the perspective of Amazon Anopheles vectors

In the Americas, areas with a high risk of malaria transmission are mainly located in the Amazon Forest, which extends across nine countries. One keystone step to understanding the Plasmodium life cycle in Anopheles species from the Amazon Region is to obtain experimentally infected mosquito vectors. Several attempts to colonise Ano- pheles species have been conducted, but with only short-lived success or no success at all. In this review, we review the literature on malaria transmission from the perspective of its Amazon vectors. Currently, it is possible to develop experimental Plasmodium vivax infection of the colonised and field-captured vectors in laboratories located close to Amazonian endemic areas. We are also reviewing studies related to the immune response to P. vivax infection of Anopheles aquasalis, a coastal mosquito species. Finally, we discuss the importance of the modulation of Plasmodium infection by the vector microbiota and also consider the anopheline genomes. The establishment of experimental mosquito infections with Plasmodium falciparum, Plasmodium yoelii and Plasmodium berghei parasites that could provide interesting models for studying malaria in the Amazonian scenario is important. Understanding the molecular mechanisms involved in the development of the parasites in New World vectors is crucial in order to better determine the interaction process and vectorial competence.     

Selected anthropometric variables and aerobic fitness as predictors of cardiovascular disease risk in children

The aim of this study was to assess the suitability of body mass index, waist circumference, waist-to-height ratio and aerobic fitness as predictors of cardiovascular risk factor clustering in children. A cross-sectional study was conducted with 290 school boys and girls from 6 to 10 years old, randomly selected. Blood was collected after a 12-hour fasting period. Blood pressure, waist circumference (WC), height and weight were evaluated according to international standards. Aerobic fitness (AF) was assessed by the 20-metre shuttle-run test. Clustering was considered when three of these factors were present: high systolic or diastolic blood pressure, high low-density lipoprotein (LDL) cholesterol, high triglycerides, high plasma glucose, high insulin concentrations and low high-density lipoprotein (HDL) cholesterol. A ROC curve identified the cut-off points of body mass index (BMI), WC, waist-to-height ratio (WHtR) and AF as predictors of risk factor clustering. BMI, WC and WHR resulted in significant areas under the ROC curves, which was not observed for AF. The anthropometric variables were good predictors of cardiovascular risk factor clustering in both sexes, whereas aerobic fitness should not be used to identify cardiovascular risk factor clustering in these children.