1,174 research outputs found

    Copyright for Scholars: Osmosis Doesn't Do the Trick Anymore

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    A review of four books: Smith, Kevin L. Owning and Using Scholarship: An IP Handbook for Teachers and Researchers; Crews, Kenneth. Copyright Law for Librarians and Educator: Creative Strategies and Practical Solutions; Butler, Rebecca P. Copyright for Academic Librarians and Professionals; Russell, Carrie. Complete Copyright for K-12 Librarians and Educators

    Neglected tropical diseases in the genomics era: re-evaluating the impact of new drugs and mass drug administration.

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    Simon Croft answers Genome Biology's questions on ways to approach neglected tropical diseases in the genomics era, including re-evaluating the impact of new drugs and mass drug administration

    Emerging paradigms in anti-infective drug design.

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    The need for new drugs to treat microbial infections is pressing. The great progress made in the middle part of the twentieth Century was followed by a period of relative inactivity as the medical needs relating to infectious disease in the wealthier nations receded. Growing realisation that anti-infectives are needed in many parts of the world, to treat neglected diseases as well as to combat the burgeoning risk of resistance to existing drugs, has galvanised a new wave of research into anti-microbial drugs. The transfer of knowledge from the Pharmaceutical industry relating to the importance of understanding how to target drugs successfully within the body, and improved understanding of how pathogens interact with their hosts, is driving a series of new paradigms in anti-infective drug design. Here we provide an overview of those processes as an introduction to a series of articles from experts in this area that emerged from a meeting entitled "Emerging Paradigms in Anti-Infective Drug Design" held in London on the 17th and 18th September 2012. The symposium was organised jointly by British Society for Parasitology (BSP) and the Biological & Medicinal Chemistry sector of the Royal Society of Chemistry (RSC) and held at the London School of Hygiene & Tropical Medicine. The symposium set out to cover all aspects of the identification of new therapeutic modalities for the treatment of neglected and tropical diseases. We aimed to bring together leading scientists from all the disciplines working in this field and cover the pharmacology, medicinal chemistry and drug delivery of potential new medicines. Sessions were held on: "Target diseases and targets for drugs", "Target based medicinal chemistry", "Bioavailability and chemistry", "Targeting intracellular microbes", "Alternative approaches and models", and "New anti-infectives - how do we get there?" This symposium was organised by Simon Croft (LSHTM) and Mike Barrett (University of Glasgow) for the BSP, and David Alker (David Alker Associates) and Andrew Stachulski (University of Liverpool) for the Biological & Medicinal Chemistry sector of the RSC

    Treatment of localised cutaneous Leishmania tropica infection in Aleppo, Syria and drug sensitivity of clinical isolates

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    Anthroponotic cutaneous leishmaniasis caused by Leishmania tropica has been endemic in Aleppo, Syria for centuries. The first modem description of the disease was also done in Aleppo. A surveillance system is in place, and the numbers of annual recorded cases have been rising from a few hundred to thousands in the late 1980s, to more than 5,000 in most years from 1990, and to more than 10,000 since 2003. A retrospective analysis of routinely collected demographic data was performed. The clinical course was examined in a subset of patients. One hundred and thirty-two patients were recruited for follow-up study. Parasites were isolated from the lesions of these patients before treatment and during the course of treatment. Eighty isolates were tested for drug sensitivity in amastigotemacrophage system and typed to species level. Molecular fingerprinting was applied to a subset of isolates. Interviews were held with patients or accompanying adults about their knowledge, attitudes and practices regarding prevention, diagnosis and treatment. Leishmaniasis patients in Aleppo were younger than the general population (median age 13 vs. 19 years), and females predominated among adults. Children and males were more likely to have lesions on the face. Smear positivity decreased with patient age (OR=O.5 in over-forties compared to under-tens). Smear positivity peaked at two-month lesion duration (OR=2.2 compared to lesion duration of <1 month). A significant proportion of patients, especially adults, did not complete their treatment course. The isolated parasites were insensitive (median ECso=229 fig Sbv Iml) to pentavalent antimony, the drug used in Aleppo, and to paromomycin but were sensitive to amphotericin B. No relationship was found between baseline parasite in vitro sensitivity and treatment duration. All the typed parasites were L. tropica. Parasite schizodemes clustered by place of isolation and by family

    New drugs against trypanosomatid parasites : rediscovery of fexinidazole

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    Neglected tropical diseases (NTDs) are a group of communicable diseases mostly affecting people in developing countries. These diseases are responsible for a major part of the global morbidity, mortality and poverty. There is no doubt that the well-being of people in the developing world can only be improved if the NTDs are controlled. An important tool for disease control is the drug treatment. The few available drugs are unsatisfactory because of the limited efficacy, adverse effects and the high price. Chagas disease, leishmaniasis and human African trypanosomiasis belong to this group of NTDs. They are caused by infections with protozoa of the family Trypanosomatidae. For these three diseases new drugs are urgently needed. By definition there is no commercial market for drugs against NTDs. Drug research and development (R&D) for NTDs is mainly driven by the public sector, the so-called product development partnerships (PDPs). Drug R&D is a very long (10-15 years), risky and therefore expensive process. Three different series of compounds (agrochemicals, marketed drugs and nitro-heterocyclic compounds) were tested for their antiparasitic effects, with the aim to identify new lead compounds or even clinical candidates against leishmaniasis, sleeping sickness, and Chagas disease. Agrochemicals are used worldwide on a large scale in food production. They undergo a rigorous toxicological testing prior to launch. Over 600 compounds were screened for their antiparasitic activity. Agrochemicals are not optimized for use in mammals, yet a significant number of molecules were found with good and selective in vitro activity. Some of them showed also efficacy in the corresponding rodent model. These results indicate that agrochemicals can provide very interesting starting structures for drug research against parasitic diseases. Drugs or drug-like compounds are an ideal starting point for antiparasitic drug discovery, because very often pharmacokinetic and toxicological data are available. A number of drugs, including antibiotics, antivirals, antifungals, and anti-psychotics were assayed for antiparasitic activity. Some of the drugs tested showed selective antiparasitic activity. These compounds can be regarded as new lead structures and should be further investigated. Nitroheterocycles belong to a well- known class of compounds with the stigma of being mutagenic or genotoxic. Over 700 compounds, mainly nitroimidazoles, have been systematically tested for their antiparasitic activity, and their pharmacokinetics and mutagenicity was investigated. A number of effective, non-mutagenic and non- genotoxic compounds was identified. So fexinidazole was rediscovered, a drug that had been in clinical development already in the 70’s as a broad-spectrum antimicrobial drug. Fexinidazole is rapidly metabolized to fexinidazole-sulfoxide and -sulfone. The parent compound and the two principle metabolites showed in vitro trypanocidal activity against all (sensitive and resistant) tested T. brucei strains (IC50 of 0.2 - 0.9 ug / ml). Fexinidazole cured the first stage mouse model with a 4-day oral treatment of 100 mg/kg/day and the 2nd stage mouse model with a 5-day oral treatment of 200 mg/kg/day. The two metabolites are mainly responsible for the good efficacy in animal models. Both reach very high concentrations in blood and brain tissue. Fexinidazole has successfully completed preclinical development and Phase I clinical trials and is currently in a clinical phase II / III study. With the approach of phenotypic screening of compounds that have been developed for other purposes, new leads for drug R&D against Chagas’ disease, leishmaniasis and human African trypanosomiasis were identified. Fexinidazole is the first drug candidate in clinical Phase II / III trials since decades. It would be the first oral drug for the treatment of stage 1 and 2 of human African sleeping sickness. If fexinidazole overcomes all obstacles, this would be a major breakthrough in the fight against African sleeping sickness. With a well tolerated, orally active drug like Fexinidazole the elimination of sleeping sickness seems finally tangible

    Archaeological and environmental investigations of Late Glacial and Holocene river valley sequences on the River Soar, at Croft, Leicestershire

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    The sediments, stratigraphy and archaeology of several sections through Lateglacial and Holocene deposits associated with the past course of the Thurlston Brook at Croft, Leicestershire, UK are outlined. The results of pollen, plant macrofossil and insect analyses from these deposits are presented and this information is used to provide a detailed reconstruction of changing river conditions and human land use at this location during the Holocene. Despite the presence of hiatuses in the record seen at Croft, and other sites of this scale, with accurate work and clear dating controls it is possible to 'stitch' together continuous detailed sequences. The general pattern of Holocene landscape and fluvial change appears to echo that seen in the Trent valley region and nationally. It is suggested that small headwater catchments such as at Croft have the potential to provide detailed and sensitive records of Holocene events comparable with those from 'standard' sediment sequences

    In vitro studies and in vivo evaluation of novel diamidines for 2nd stage sleeping sickness

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    Summary: African sleeping sickness is one of the most neglected tropical diseases. Transmitted by the tsetse fly it exclusively occurs in sub-Saharan Africa. It is caused by two different parasite subspecies causing two different forms of African sleeping sickness. Trypanosoma brucei gambiense is prevalent in West and Central Africa while Trypanosoma brucei rhodesiense is prevalent in East and South Africa. Sleeping sickness is classified in two main stages. In the first stage, the parasites reside in the lymph and blood system. In the second stage, the parasites additionally infect the brain. Untreated sleeping sickness is fatal. Drugs are available for this fearsome disease, however, most of them are old and have many drawbacks, such as severe adverse effects, treatment failures and complicated treatment schedules, which is a problem in remote rural areas where the disease primarily occurs. African sleeping sickness is a communicable disease that can be controlled. In 1998, there were an estimated 300,000 cases. By 2012 the prevalence has decreased to about 30,000, by different control measures such as vector control, improved surveillance and free drug distribution. Elimination seems possible, but safe and effective drugs are needed to reach this goal. One of the current drugs is the diamidine pentamidine which is in use since the early 1940s. However, it works only in patients with first stage disease and it has to be injected. The Consortium for Parasitic Drug Development (CPDD) was founded in the year 2000 to find novel diamidines with better characteristics than the existing drugs. We improved oral absorption, which makes it possible to use pills instead of injections, and central nervous system (CNS) penetration. One compound (pafuramidine) has been tested in patients with first stage infections. It was the first compound that cured sleeping sickness orally, which is of great help for rural areas. Unfortunately, pafuramidine caused kidney and liver problems, and it did not cure second stage infections. In the meantime, we have identified superior compounds especially for the second stage. As described in Chapter 3, two compounds, the prodrugs DB868 and DB844, given orally, cured all mice with CNS infections. However, both prodrugs were too toxic at the high doses required to cure both stages in monkeys. Nevertheless, DB868 is a good candidate drug to cure first stage sleeping sickness by an oral treatment, as demonstrated in mice and monkeys with first stage infections. Chapter 4 shows data of another CNS potent prodrug, DB1227 which was, however, less effective than DB868 in CNS infected mice. Chapters 3, 7, 8 and 9 deal with two unmasked diamidines, DB829 and 28DAP010, which were highly effective in mice with second stage infections after i.p. injection. This was unexpected since diamidines are rather unlikely to cross the blood brain barrier in sufficient concentrations by diffusion. These two diamidines may penetrate into the brain by specific transporter proteins. The advantage of the two diamidines is that both cure with a short treatment course which could shorten the time of hospitalization of the patients. We have already tested DB829 in monkeys with promising results. It was safe and effective at low doses and a short treatment schedule in monkeys with second stage disease. 28DAP010 seems to be similarly effective as DB829 on both T. brucei subspecies in vitro and in mouse models. In Chapter 6 we established a new in vitro method to measure the kinetics of drug action on pathogenic protozoa on a real time basis. We exploited the capacity of viable cells to produce heat and measured the heat flow using microcalorimetry. 28DAP010 inhibited the heat production of trypanosome cultures faster than DB829. The parasite clearance time of 28DAP010 was also faster than of DB829 in mice. The required effective treatment duration was still similar in mice with single dose for first stage and 5 days for second stage infections. Upcoming efficacy studies will reveal if 28DAP010 is as curative in monkeys as DB829 and toxicity studies of 28DAP010 and DB829 side by side will shed light on their toxicity profile. These studies will help to select the better of these two compounds as a clinical drug candidate for the treatment of second stage sleeping sickness. ---------- Zusammenfassung: Die Afrikanische Schlafkrankheit ist eine Tropenkrankheit, welche durch die Tsetsefliege übertragen wird und daher ausschliesslich im tropischen Afrika vorkommt. Sie gehört zu den vernachlässigsten Krankheiten überhaupt und wird deshalb auch “vergessene Seuche“ genannt. Der Erreger ist ein einzelliger Parasit. Es gibt zwei verschiedene Unterarten, die zu etwas unterschiedlichen Schlafkrankheitsformen führen. Ohne wirksame Medikamentenbehandlung sind beide Formen tödlich. Trypanosoma brucei gambiense kommt nur in West- und Zentralafrika vor, während Trypanosoma brucei rhodesiense in Ost- und Südafrika zu finden ist. Der Krankheitsverlauf kann in zwei Stadien unterteilt werden. Im ersten Stadium findet man die Parasiten im Blut- und Lymphsystem und im zweiten Stadium zusätzlich im Gehirn. Zwar gibt es für diese Krankheit Medikamente, jedoch sind die meisten davon veraltet, haben ausgeprägte Nebenwirkungen und sind wegen Rückfällen oder der komplizierten und aufwendigen Behandlung problematisch. Die Bekämpfung der Afrikanischen Schlafkrankheit ist möglich. 1998 gab es geschätzt etwa 300.000 Krankheitsfälle. Durch verbesserte Überwachung mit anschliessender medizinischer Behandlung der Infizierten, kostenlose Medikamentenverteilung und Vektorkontrolle, liess sich die Krankheit auf etwa 30.000 Krankheitsfälle im Jahr 2012, eindämmen. Für eine Eliminierung sind wirksame und verträgliche Medikamente notwendig. Ein Diamidin, das schon seit den frühen 40-er Jahren eingesetzt wird ist Pentamidin. Es wirkt noch heute, aber nur in Patienten die sich im ersten Stadium befinden, zudem muss es injiziert werden. Im Jahr 2000 wurde das Konsortium CPDD, für die Entwicklung neuer Wirkstoffe zur Behandlung parasitärer Erkrankungen, vor allem für die Schlafkrankheit, gegründet. Neuartige Diamidine mit verbesserten Eigenschaften wurden gesucht und es war uns möglich, die orale Bioverfügbarkeit und die Bluthirnschrankengängigkeit, chemisch zu verbessern. Pafuramidin, war einer der neuen Wirkstoffe, das erste oral einzunehmende Medikament gegen Schlafkrankheit, das im Menschen getestet wurde. Ein orales Medikament hat grosse Vorteile für diese Krankheit, die hauptsächlich in abgelegenen Gebieten Afrikas vorkommt, wo ein ausgebautes Gesundheitssystem oft fehlt. Pafuramidin heilte nur das erste Schlafkrankheitsstadium und dabei wurden Leber- und Nieren-Unverträglichkeiten festgestellt. Während der klinischen Studie testeten wir weitere Diamidine und fanden verbesserte Substanzen, vor allem bezüglich der Wirksamkeit des zweiten Krankheitsstadiums. Kapitel 3 und 4 beschreibt die wirksamsten Moleküle, die das Zweitstadium bei oraler Verabreichung heilten. Diese Moleküle, DB844, DB868, DB1227, aber auch das Pafuramidin sind Medikamenten-vorstufen (Prodrugs). Diese wurden entwickelt, um die orale Aufnahme und Gehirn-gängigkeit zu verbessern. Die aktivsten waren DB868 und DB844 in Mäusen, jedoch zeigten beide Moleküle toxische Wirkungen im Affen ohne dabei ausreichend die Gehirninfektion zu heilen. Dennoch war DB868 im Affenmodell deutlich besser verträglich als Pafuramidin und ist somit ein guter Ersatzkandidat für eine orale Wirkstoffentwicklung fürs erste Stadium. Unerwartet konnten wir jedoch zwei Diamidine (ohne Vorstufenergänzung) identifizieren, die ebenfalls Mäuse mit Gehirninfektionen heilten. Da Diamidine unter physiologischen Bedingungen protoniert sind, ist es unwahrscheinlich, dass sie durch die Bluthirnschranke diffundieren. Möglicherweise werden sie über spezifische Mechanismen ins Gehirn transportiert. Kapitel 3, 7, 8 und 9 befassen sich mit den beiden aktivsten Diamidinen, DB829 und 28DAP010. Ihre hohe Wirkung und die kurze Behandlungszeit nach parenteraler Verabreichung (i.p. oder i.m) sind vielversprechend. DB829 war gut verträglich und wirksam bei niedrigen Dosen und heilte die infizierten Affen mit dem zweiten Krankheitsstadium bereits bei einer 5-tägigen Behandlung. In vitro und im Mausmodel war 28DAP010 auf beide Trypanosomen Unterarten ähnlich wirksam wie DB829. Um die Wirkungszeit neuer Substanzen auf Trypanosomen zu testen, entwickelten wir eine neue Methode, die in Kapitel 6 beschrieben wird. Dabei nutzten wir die Eigenschaft der Zellen, Wärme zu produzieren und massen diese mit einem Kalorimeter auf Echtzeit. 28DAP010 reduzierte die Wärmeentwicklung einer Trypanosomenkultur deutlich schneller als DB829. Auch in infizierten Mäusen wirkte 28DAP010 schneller. Die Behandlungsdauer und Dosierung war bei beiden Diamidinen trotzdem vergleichbar. Eine Einzeldosis heilte das erste und eine 5-tägige Behandlung das zweite Stadium in Mäusen. Weitere Studien sind nötig, um die Wirksamkeit von 28DAP010 im Affenmodel zu überprüfen und die Verträglichkeit beider Diamidine zu analysieren. Diese Ergebnisse werden zeigen, welches der bessere klinische Kandidat für die Behandlung des zweiten Schlafkrankheitsstadiums sein wird

    Management of trypanosomiasis and leishmaniasis

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    &lt;p&gt;Background: The current treatments for human African trypanosomiasis (HAT), Chagas disease and leishmaniasis (collectively referred to as the kinetoplastid diseases) are far from ideal but, for some, there has been significant recent progress. For HAT the only advances in treatment over the past two decades have been the introduction of an eflornithine/nifurtimox co-administration and a shorter regime of the old standard melarsoprol.&lt;/p&gt; &lt;p&gt;Sources of data: PubMed.&lt;/p&gt; &lt;p&gt;Areas of Agreement: There is a need for new safe, oral drugs for cost-effective treatment of patients and use in control programmes for all the trypanosomatid diseases.&lt;/p&gt; &lt;p&gt;Areas of controversy: Cutaneous leishmaniasis is not on the agenda and treatments are lagging behind.&lt;/p&gt; &lt;p&gt;Growing points: There are three compounds in development for the treatment of the CNS stage of HAT: fexinidazole, currently due to entry into phase II clinical studies, a benzoxaborole (SCYX-7158) in phase I trials and a diamidine derivative (CPD-0802), in advanced pre-clinical development. For Chagas disease, two anti-fungal triazoles are now in clinical trial. In addition, clinical studies with benznidazole, a drug previously recommended only for acute stage treatment, are close to completion to determine the effectiveness in the treatment of early chronic and indeterminate Chagas disease. For visceral leishmaniasis new formulations, therapeutic switching, in particular AmBisome, and the potential for combinations of established drugs have significantly improved the opportunities for the treatment in the Indian subcontinent, but not in East Africa.&lt;/p&gt; &lt;p&gt;Areas timely for developing research: Improved diagnostic tools are needed to support treatment, for test of cure in clinical trials and for monitoring/surveillance of populations in control programmes.&lt;/p&gt

    Pharmacological Approaches to Antitrypanosomal Chemotherapy

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    There is an urgent need for new drugs for the chemotherapy of human African trypanosomiasis, Chagas disease and leishmaniasis. Progress has been made in the identification and characterization of novel drug targets for rational chemotherapy and inhibitors of trypanosomatid glycosomal enzymes, trypanothione reductase, ornithine decarboxylase, S-adenosylmethionine decarboxylase, cysteine proteases and of the purine and sterol biosynthetic pathways. However, less attention has been paid to the pharmacological aspects of drug design or to the use of drug delivery systems in the chemotherapy of African trypanosomiasis and Chagas disease. A review of research on pharmacology and drug delivery systems shows that there are new opportunities for improving the chemotherapy of these diseases
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