Your search keyword '"filarial diseases"' showing total 12 results

1. Repurposed Drugs That Activate Autophagy in Filarial Worms Act as Effective Macrofilaricides.

Author

Voronin, Denis, Tricoche, Nancy, Peguero, Ricardo, Kaminska, Anna Maria, Ghedin, Elodie, Sakanari, Judy A., and Lustigman, Sara

Subjects

*FILARIAL worms, *FILARIASIS, *ONCHOCERCA volvulus, *AUTOPHAGY, *HUMAN reproduction

Abstract

Onchocerciasis and lymphatic filariasis are two neglected tropical diseases caused by filarial nematodes that utilize insect vectors for transmission to their human hosts. Current control strategies are based on annual or biannual mass drug administration (MDA) of the drugs Ivermectin or Ivermectin plus Albendazole, respectively. These drug regimens kill the first-stage larvae of filarial worms (i.e., microfilariae) and interrupt the transmission of infections. MDA programs for these microfilaricidal drugs must be given over the lifetime of the filarial adult worms, which can reach 15 years in the case of Onchocerca volvulus. This is problematic because of suboptimal responses to ivermectin in various endemic regions and inefficient reduction of transmission even after decades of MDA. There is an urgent need for the development of novel alternative treatments to support the 2030 elimination goals of onchocerciasis and lymphatic filariasis. One successful approach has been to target Wolbachia, obligatory endosymbiotic bacteria on which filarial worms are dependent for their survival and reproduction within the human host. A 4–6-week antibiotic therapy with doxycycline, for example, resulted in the loss of Wolbachia that subsequently led to extensive apoptosis of somatic cells, germline, embryos, and microfilariae, as well as inhibition of fourth-stage larval development. However, this long-course regimen has limited use in MDA programs. As an alternative approach to the use of bacteriostatic antibiotics, in this study, we focused on autophagy-inducing compounds, which we hypothesized could disturb various pathways involved in the interdependency between Wolbachia and filarial worms. We demonstrated that several such compounds, including Niclosamide, an FDA-approved drug, Niclosamide ethanolamine (NEN), and Rottlerin, a natural product derived from Kamala trees, significantly reduced the levels of Wolbachia in vitro. Moreover, when these compounds were used in vivo to treat Brugia pahangi-infected gerbils, Niclosamide and NEN significantly decreased adult worm survival, reduced the release of microfilariae, and decreased embryonic development depending on the regimen and dose used. All three drugs given orally significantly reduced Wolbachia loads and induced an increase in levels of lysosome-associated membrane protein in worms from treated animals, suggesting that Niclosamide, NEN, and Rottlerin were effective in causing drug-induced autophagy in these filarial worms. These repurposed drugs provide a new avenue for the clearance of adult worms in filarial infections. [ABSTRACT FROM AUTHOR]

Published

2024

2. Repurposed Drugs That Activate Autophagy in Filarial Worms Act as Effective Macrofilaricides

Author

Denis Voronin, Nancy Tricoche, Ricardo Peguero, Anna Maria Kaminska, Elodie Ghedin, Judy A. Sakanari, and Sara Lustigman

Subjects

Wolbachia, autophagy, repurposed drugs, filarial diseases, macrofilaricidal drugs, Pharmacy and materia medica, RS1-441

Abstract

Onchocerciasis and lymphatic filariasis are two neglected tropical diseases caused by filarial nematodes that utilize insect vectors for transmission to their human hosts. Current control strategies are based on annual or biannual mass drug administration (MDA) of the drugs Ivermectin or Ivermectin plus Albendazole, respectively. These drug regimens kill the first-stage larvae of filarial worms (i.e., microfilariae) and interrupt the transmission of infections. MDA programs for these microfilaricidal drugs must be given over the lifetime of the filarial adult worms, which can reach 15 years in the case of Onchocerca volvulus. This is problematic because of suboptimal responses to ivermectin in various endemic regions and inefficient reduction of transmission even after decades of MDA. There is an urgent need for the development of novel alternative treatments to support the 2030 elimination goals of onchocerciasis and lymphatic filariasis. One successful approach has been to target Wolbachia, obligatory endosymbiotic bacteria on which filarial worms are dependent for their survival and reproduction within the human host. A 4–6-week antibiotic therapy with doxycycline, for example, resulted in the loss of Wolbachia that subsequently led to extensive apoptosis of somatic cells, germline, embryos, and microfilariae, as well as inhibition of fourth-stage larval development. However, this long-course regimen has limited use in MDA programs. As an alternative approach to the use of bacteriostatic antibiotics, in this study, we focused on autophagy-inducing compounds, which we hypothesized could disturb various pathways involved in the interdependency between Wolbachia and filarial worms. We demonstrated that several such compounds, including Niclosamide, an FDA-approved drug, Niclosamide ethanolamine (NEN), and Rottlerin, a natural product derived from Kamala trees, significantly reduced the levels of Wolbachia in vitro. Moreover, when these compounds were used in vivo to treat Brugia pahangi-infected gerbils, Niclosamide and NEN significantly decreased adult worm survival, reduced the release of microfilariae, and decreased embryonic development depending on the regimen and dose used. All three drugs given orally significantly reduced Wolbachia loads and induced an increase in levels of lysosome-associated membrane protein in worms from treated animals, suggesting that Niclosamide, NEN, and Rottlerin were effective in causing drug-induced autophagy in these filarial worms. These repurposed drugs provide a new avenue for the clearance of adult worms in filarial infections.

Published

2024

3. Molecular docking-based virtual screening, molecular dynamic simulation, and 3-D QSAR modeling of some pyrazolopyrimidine analogs as potent anti-filarial agents.

Author

Ugbe, Fabian Audu, Shallangwa, Gideon Adamu, Uzairu, Adamu, and Abdulkadir, Ibrahim

Subjects

*MOLECULAR docking, *QSAR models, *FILARIASIS, *DYNAMIC simulation, *PROTEIN-ligand interactions, *FILARIAL worms, *QUINAZOLINONES

Abstract

Lymphatic filariasis and onchocerciasis are common filarial diseases caused by filarial worms, which co-habit symbiotically with the Wolbachia organism. One good treatment method seeks Wolbachia as a drug target. Here, a computer-aided molecular docking screening and 3-D QSAR modeling were conducted on a series of Fifty-two (52) pyrazolopyrimidine derivatives against four Wolbachia receptors, including a pharmacokinetics study and Molecular Dynamic (MD) investigation, to find a more potent anti-filarial drug. The DFT approach (B3LYP with 6-31G** option) was used for the structural optimization. Five ligand-protein interaction pairs with the highest binding affinities were identified in the order; 23_7ESX (-10.2 kcal/mol) > 14_6EEZ (− 9.0) > 29_3F4R (− 8.0) > 26_6W9O (− 7.7) ≈ doxycycline_7ESX (− 7.7), with good pharmacological interaction profiles. The built 3-D QSAR model satisfied the requirement of a good model with R2 = 0.9425, Q2LOO = 0.5019, SDEC = 0.1446, and F test = 98.282. The selected molecules (14, 23, 26, and 29) perfectly obeyed Lipinski's RO5 for oral bio-availability, and showed excellent ADMET properties, except 14 with positive AMES toxicity. The result of the MD simulation showed the great stability associated with the binding of 23 onto 7ESX's binding pocket with an estimated binding free energy (MM/GBSA) of − 60.6552 kcal/mol. Therefore, 23 could be recommended as a potential anti-filarial drug molecule, and/or template for the design of more prominent inhibitors. [ABSTRACT FROM AUTHOR]

Published

2022

4. Molecular Docking Screening and Pharmacokinetic Studies of Some Boron-Pleuromutilin Analogues against Possible Targets of Wolbachia pipientis

Author

Fabian Audu Ugbe, Gideon Adamu Shallangwa, Adamu Uzairu, and Ibrahim Abdulkadir

Subjects

Pleuromutilins, Wolbachia, filarial diseases, molecular docking, pharmacokinetics, Pharmacy and materia medica, RS1-441, Chemistry, QD1-999

Abstract

Lymphatic filariasis and onchocerciasis are two common filarial diseases caused by a group of parasitic nematodes called filarial worms, which co-habit with the bacteria organism Wolbachia. One good treatment approach seeks Wolbachia as a drug target. Here, a computer-aided molecular docking screening was conducted on a series of 52 pleuromutilin analogs against four Wolbachia enzymes: α-DsbA1 (PDB: 3F4R), α-DsbA2 (6EEZ), OTU deubiquitinase (6W9O), and cytoplasmic incompatibility factor CidA (7ESX) to find a more potent drug candidate(s) for the treatment of filarial diseases. The docking investigation was performed using the iGEMDOCK tool, while NAMD was utilized for the Molecular Dynamic (MD) simulation. The results of the virtual screening identified four ligand-protein interaction pairs with the highest binding affinities in the order: 17_6W9O (-117.31 kcal/mol) > 28_6EEZ (-104.43 kcal/mol) > 17_7ESX (-102.56 kcal/mol) > 41_7ESX (-101.51 kcal/mol), greater than that of the reference drug doxycycline_7ESX (-92.15 kcal/mol). These molecules (17, 28, and 41) showed excellent binding interactions, making very close contact with the receptors’ amino acid residues. They also showed better pharmacokinetic properties than doxycycline because they showed high intestinal absorption, were orally bioavailable and showed no AMES toxicity. Also, the stability of 17_6W9O interactions was confirmed by the MD simulation. Therefore, the selected molecules could be developed as potential drug candidates for treating filarial diseases.

Published

2022

5. Theoretical modeling and design of some pyrazolopyrimidine derivatives as Wolbachia inhibitors, targeting lymphatic filariasis and onchocerciasis.

Author

Ugbe, Fabian Audu, Shallangwa, Gideon Adamu, Uzairu, Adamu, and Abdulkadir, Ibrahim

Subjects

*ONCHOCERCIASIS, *FILARIASIS, *WOLBACHIA, *PROTEIN-ligand interactions, *DENSITY functional theory

Abstract

Lymphatic filariasis and onchocerciasis are two common filarial diseases caused by a group of parasitic nematodes called filarial worms, which play host to the bacteria organism Wolbachia. One good treatment approach seeks Wolbachia as drug target. Here, a QSAR study was conducted to investigate the anti-wolbachia activities (pEC50) of 52 pyrazolopyrimidine analogues, while using the built model to predict the pEC50 values of the newly designed analogues. Density Functional Theory was used for the structural optimization, while the model building was based on Genetic Function Algorithm approach. The built QSAR model was validated thus: R2 = 0.8104, R2adj = 0.7629, Q2cv = 0.6981, R2test = 0.7501 and cRp2 = 0.7476. The predicted pEC50 of all newly designed compounds were higher than that of the template (43). The new compounds were; observed to pass the drug-likeness criteria, uniformly distributed to the brain, and found to be non-mutagenic. Also, the new compounds and the reference drug (doxycycline), were docked onto Ovarian Tumor (OTU) deubiquitinase receptor (PDB ID: 6W9O) using iGEMDOCK tool. This protein is known to help Wolbachia subvert host ubiquitin signaling. The resulting binding scores of the newly designed compounds except A5 were higher than that of doxycycline, while the protein–ligand interactions were majorly characterized by Hydrogen-bonding and hydrophobic interaction types. Therefore, the newly designed molecules could be developed as potential drug candidates for the treatment of lymphatic filariasis and onchocerciasis. [ABSTRACT FROM AUTHOR]

Published

2022

6. Pyrvinium Pamoate and Structural Analogs Are Early Macrofilaricide Leads

Author

Emma L. Gunderson, Clifford Bryant, Christina A. Bulman, Chelsea Fischer, Mona Luo, Ian Vogel, Kee-Chong Lim, Shabnam Jawahar, Nancy Tricoche, Denis Voronin, Christopher Corbo, Rene B. Ayiseh, Faustin P. T. Manfo, Glory E. Mbah, Fidelis Cho-Ngwa, Brenda Beerntsen, Adam R. Renslo, Sara Lustigman, and Judy A. Sakanari

Subjects

repurposed drugs, pyrvinium pamoate, filarial diseases, macrofilaricides, Medicine, Pharmacy and materia medica, RS1-441

Abstract

Onchocerciasis and lymphatic filariasis are neglected tropical diseases caused by infection with filarial worms. Annual or biannual mass drug administration with microfilaricidal drugs that kill the microfilarial stages of the parasites has helped reduce infection rates and thus prevent transmission of both infections. However, success depends on high population coverage that is maintained for the duration of the adult worm’s lifespan. Given that these filarial worms can live up to 14 years in their human hosts, a macrofilaricidal drug would vastly accelerate elimination efforts. Here, we have evaluated the repurposed drug pyrvinium pamoate as well as newly synthesized analogs of pyrvinium for their efficacy against filarial worms in vitro and in vivo. We found that pyrvinium pamoate, tetrahydropyrvinium and one of the analogs were highly potent in inhibiting worms in in vitro whole-worm screening assays, and that all three compounds reduced female worm fecundity and inhibited embryogenesis in the Brugia pahangi-gerbil in vivo model of infection.

Published

2022

7. XMorpher: Full Transformer for Deformable Medical Image Registration via Cross Attention

Author

Shi, Jiacheng, He, Yuting, Kong, Youyong, Coatrieux, Jean-Louis, Shu, Huazhong, Yang, Guanyu, Li, Shuo, Laboratory of Image Science and Technology [Nanjing] (LIST), Southeast University [Jiangsu]-School of Computer Science and Engineering, Centre de Recherche en Information Biomédicale sino-français (CRIBS), Université de Rennes (UR)-Southeast University [Jiangsu]-Institut National de la Santé et de la Recherche Médicale (INSERM), Laboratoire Traitement du Signal et de l'Image (LTSI), Université de Rennes (UR)-Institut National de la Santé et de la Recherche Médicale (INSERM), University of Western Ontario (UWO), National Natural Science Foundation [62171125, 61828101], CAAI-Huawei MindSpore Open Fund, CANN (Compute Architecture for Neural Networks), Ascend AI Processor, Big Data Computing Center of Southeast University, Wang, Dou, Fletcher, PT, Speidel, and Li

Subjects

FOS: Computer and information sciences, Filarial diseases, Pyrazolopyrimidine, Computer Vision and Pattern Recognition (cs.CV), Molecular docking, Computer Science - Computer Vision and Pattern Recognition, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Pharmacokinetics, [SDV.IB]Life Sciences [q-bio]/Bioengineering, 3-D QSAR, Molecular dynamics, Wolbachia

Abstract

An effective backbone network is important to deep learning-based Deformable Medical Image Registration (DMIR), because it extracts and matches the features between two images to discover the mutual correspondence for fine registration. However, the existing deep networks focus on single image situation and are limited in registration task which is performed on paired images. Therefore, we advance a novel backbone network, XMorpher, for the effective corresponding feature representation in DMIR. 1) It proposes a novel full transformer architecture including dual parallel feature extraction networks which exchange information through cross attention, thus discovering multi-level semantic correspondence while extracting respective features gradually for final effective registration. 2) It advances the Cross Attention Transformer (CAT) blocks to establish the attention mechanism between images which is able to find the correspondence automatically and prompts the features to fuse efficiently in the network. 3) It constrains the attention computation between base windows and searching windows with different sizes, and thus focuses on the local transformation of deformable registration and enhances the computing efficiency at the same time. Without any bells and whistles, our XMorpher gives Voxelmorph 2.8% improvement on DSC , demonstrating its effective representation of the features from the paired images in DMIR. We believe that our XMorpher has great application potential in more paired medical images. Our XMorpher is open on https://github.com/Solemoon/XMorpher, Comment: accepted by MICCAI 2022

Published

2022

8. In vivo preliminary investigations of the effects of the benzimidazole anthelmintic drug flubendazole on rat embryos and fetuses.

Author

Longo, Monica, Zanoncelli, Sara, Messina, Monica, Scandale, Ivan, Mackenzie, Charles, Geary, Timothy, Marsh, Kennan, Lindley, David, and Mazué, Guy

Subjects

*ANTHELMINTICS, *BIOAVAILABILITY, *DRUG development, *TREATMENT of filariasis, *BENZIMIDAZOLES, *EMBRYOLOGY, *LABORATORY rats, *THERAPEUTICS

Abstract

Flubendazole, in a new formulation with high systemic bioavailability, has been proposed as a macrofilaricide against filarial diseases. To investigate embryotoxic activity, the new flubendazole formulation was administered orally to Sprague Dawley rats at 2, 3.46, 6.32 mg/kg/day on gestation day (GD) 9.5 and 10.5. Embryos/fetuses were evaluated on GD 11.5, 12.5 or 20. At 6.32 mg/kg/day ( C max = 0.801 μg/mL after single administration), flubendazole initially induced an arrest of embryonic development followed by a generalized cell death that led to 100% embryolethality by GD 12.5. At 3.46 mg/kg/day ( C max = 0.539 μg/mL after single administration), flubendazole markedly reduced embryonic development by GD 12.5 without causing cell death. On GD 20, 80% of fetuses showed malformations. At 2 mg/kg/day ( C max = 0.389 μg/mL after single administration), it did not interfere with rat embryofetal development. [ABSTRACT FROM AUTHOR]

Published

2014

9. Effects of the benzimidazole anthelmintic drug flubendazole on rat embryos in vitro

Author

Longo, Monica, Zanoncelli, Sara, Colombo, Paolo Angelo, Harhay, Michael Oscar, Scandale, Ivan, Mackenzie, Charles, Geary, Timothy, Madrill, Nicole, and Mazué, Guy

Subjects

*BENZIMIDAZOLES, *LABORATORY rats, *IN vitro studies, *TREATMENT of filariasis, *DRUG efficacy, *EMBRYOLOGY, *HYDROLYSIS, *METABOLITES

Abstract

Abstract: Filarial diseases affect millions of people in poverty-stricken areas. In 2011, an investigation of the potential of flubendazole as a safe, highly efficacious, and field-usable macrofilaricidal drug was begun by Drug for Neglected Diseases initiative. As part of the preclinical development program, whole embryo culture was used to investigate the potential embryotoxicity of flubendazole and its metabolites, reduced and hydrolyzed flubendazole. Albendazole was included as a comparator. Flubendazole and albendazole showed similar potency in affecting rat embryonic development in vitro, inducing retardation of growth and dysmorphogenic effects at concentrations ≥0.5μg/mL. The head, optic and otic systems, branchial arches and posterior body portion were affected. Diffuse areas of cell death were seen in various embryonic districts. The No Observed Effect Level (NOEL) was 0.25μg/mL for both drugs. Reduced and hydrolyzed flubendazole were less embryotoxic than the parent compound, with NOELs 4-fold and >40-fold higher than that of flubendazole, respectively. [Copyright &y& Elsevier]

Published

2013

10. Filariasis in Africa-treatment challenges and prospects.

Author

Hoerauf, A., Pfarr, K., Mand, S., Debrah, A. Y., and Specht, S.

Subjects

*TREATMENT of filariasis, *NEMATODES, *LYMPHEDEMA, *LYMPH circulation disorders

Abstract

Lymphatic filariasis (LF) and onchocerciasis are parasitic nematode infections that are responsible for a major disease burden in the African continent. Disease symptoms are induced by the immune reactions of the host, with lymphoedema and hydrocoele in LF, and dermatitis and ocular inflammation in onchocerciasis. Wuchereria bancrofti and Onchocerca volvulus, the species causing LF and onchocerciasis in Africa, live in mutual symbiosis with Wolbachia endobacteria, which cause a major part of the inflammation leading to symptoms and are antibiotic targets for treatment. The standard microfilaricidal drugs ivermectin and albendazole are used in mass drug administration programmes, with the aim of interrupting transmission, with a consequent reduction in the burden of infection and, in some situations, leading to regional elimination of LF and onchocerciasis. Co-endemicity of Loa loa with W. bancrofti or O. volvulus is an impediment to mass drug administration with ivermectin and albendazole, owing to the risk of encephalopathy being encountered upon administration of ivermectin. Research into new treatment options is exploring several improved delivery strategies for the classic drugs or new antibiotic treatment regimens for anti-wolbachial chemotherapy. [ABSTRACT FROM AUTHOR]

Published

2011

11. Pyrvinium Pamoate and Structural Analogs Are Early Macrofilaricide Leads.

Author

Gunderson, Emma L., Bryant, Clifford, Bulman, Christina A., Fischer, Chelsea, Luo, Mona, Vogel, Ian, Lim, Kee-Chong, Jawahar, Shabnam, Tricoche, Nancy, Voronin, Denis, Corbo, Christopher, Ayiseh, Rene B., Manfo, Faustin P. T., Mbah, Glory E., Cho-Ngwa, Fidelis, Beerntsen, Brenda, Renslo, Adam R., Lustigman, Sara, and Sakanari, Judy A.

Subjects

*FILARIAL worms, *FILARIASIS, *ONCHOCERCIASIS, *DRUG administration, *TROPICAL medicine, *MEDICAL screening

Abstract

Onchocerciasis and lymphatic filariasis are neglected tropical diseases caused by infection with filarial worms. Annual or biannual mass drug administration with microfilaricidal drugs that kill the microfilarial stages of the parasites has helped reduce infection rates and thus prevent transmission of both infections. However, success depends on high population coverage that is maintained for the duration of the adult worm's lifespan. Given that these filarial worms can live up to 14 years in their human hosts, a macrofilaricidal drug would vastly accelerate elimination efforts. Here, we have evaluated the repurposed drug pyrvinium pamoate as well as newly synthesized analogs of pyrvinium for their efficacy against filarial worms in vitro and in vivo. We found that pyrvinium pamoate, tetrahydropyrvinium and one of the analogs were highly potent in inhibiting worms in in vitro whole-worm screening assays, and that all three compounds reduced female worm fecundity and inhibited embryogenesis in the Brugia pahangi-gerbil in vivo model of infection. [ABSTRACT FROM AUTHOR]

Published

2022

12. Filariasis in Africa—treatment challenges and prospects

Author

Kenneth Pfarr, Alexander Yaw Debrah, Sabine Specht, Achim Hoerauf, and Sabine Mand

Subjects

Microbiology (medical), filarial diseases, Onchocerciasis, Albendazole, medicine.disease_cause, Diethylcarbamazine, treatment and research aspects, Filariasis, ivermectin, Elephantiasis, Filarial, Ivermectin, parasitic diseases, medicine, Animals, Humans, Wuchereria bancrofti, Symbiosis, Lymphatic filariasis, biology, General Medicine, AWOL, biology.organism_classification, medicine.disease, Onchocerca volvulus, Filaricides, Infectious Diseases, Africa, Immunology, diethylcarbamazine, DOLF, Loa loa, Wolbachia, medicine.drug

Abstract

Lymphatic filariasis (LF) and onchocerciasis are parasitic nematode infections that are responsible for a major disease burden in the African continent. Disease symptoms are induced by the immune reactions of the host, with lymphoedema and hydrocoele in LF, and dermatitis and ocular inflammation in onchocerciasis. Wuchereria bancrofti and Onchocerca volvulus, the species causing LF and onchocerciasis in Africa, live in mutual symbiosis with Wolbachia endobacteria, which cause a major part of the inflammation leading to symptoms and are antibiotic targets for treatment. The standard microfilaricidal drugs ivermectin and albendazole are used in mass drug administration programmes, with the aim of interrupting transmission, with a consequent reduction in the burden of infection and, in some situations, leading to regional elimination of LF and onchocerciasis. Co-endemicity of Loa loa with W. bancrofti or O. volvulus is an impediment to mass drug administration with ivermectin and albendazole, owing to the risk of encephalopathy being encountered upon administration of ivermectin. Research into new treatment options is exploring several improved delivery strategies for the classic drugs or new antibiotic treatment regimens for anti-wolbachial chemotherapy.

Published

2011