Your search keyword '"Manalo, Daria"' showing total 7 results

1. Additional file 2 of Evaluation of a real-time mobile PCR device (PCR 1100) for the detection of the rabies gene in field samples

Author

Demetria, Catalino, Kimitsuki, Kazunori, Yahiro, Takaaki, Saito, Nobuo, Hashimoto, Takehiro, Khan, Sakirul, Chu, Maria Yna Joyce, Manalo, Daria, Mananggit, Milagros, Quiambao, Beatriz, and Nishizono, Akira

Abstract

Additional file 2: Diagnostic results of experimentally infected mouse samples for different tissue.

Published

2023

2. Additional file 1 of Evaluation of a real-time mobile PCR device (PCR 1100) for the detection of the rabies gene in field samples

Author

Demetria, Catalino, Kimitsuki, Kazunori, Yahiro, Takaaki, Saito, Nobuo, Hashimoto, Takehiro, Khan, Sakirul, Chu, Maria Yna Joyce, Manalo, Daria, Mananggit, Milagros, Quiambao, Beatriz, and Nishizono, Akira

Abstract

Additional file 1: Characteristics of 49 animals.

Published

2023

3. Additional file 2 of Background and descriptive features of rabies-suspected animals in Central Luzon, Philippines

Author

Mananggit, Milagros R., Kimitsuki, Kazunori, Saito, Nobuo, Garcia, Alyssa Marie G., Lacanilao, Patricia Mae T., Ongtangco, Joely T., Velasco, Cornelio R., Rosario, Maria Victoria D., Lagayan, Maria Glofezita O., Yamada, Kentaro, Park, Chun-Ho, Inoue, Satoshi, Suzuki, Motoi, Saito-Obata, Mariko, Kamiya, Yasuhiko, Manalo, Daria L., Demetria, Catalino S., Quiambao, Beatriz P., and Nishizono, Akira

Abstract

Additional File 2. Specimen Information Sheet.

Published

2021

4. Correction: Genetic Diversity and Geographic Distribution of Genetically Distinct Rabies Viruses in the Philippines

Author

Saito, Mariko, Oshitani, Hitoshi, Orbina, Jun Ryan C., Tohma, Kentaro, de Guzman, Alice S., Kamigaki, Taro, Demetria, Catalino S., Manalo, Daria L., Miranda, Mary Elizabeth G., Noguchi, Akira, Inoue, Satoshi, and Quiambao, Beatriz P.

Subjects

lcsh:Arctic medicine. Tropical medicine, Infectious Diseases, lcsh:RC955-962, lcsh:Public aspects of medicine, Arctic medicine. Tropical medicine, RC955-962, Public Health, Environmental and Occupational Health, Correction, lcsh:RA1-1270, Public aspects of medicine, RA1-1270

Published

2013

5. Rapid in-country sequencing of whole virus genomes to inform rabies elimination programmes

Author

Brunker, Kirstyn, Jaswant, Gurdeep, Thumbi, SM, Lushasi, Kennedy, Lugelo, Ahmed, Czupryna, Anna M, Ade, Fred, Wambura, Gati, Chuchu, Veronicah, Steenson, Rachel, Ngeleja, Chanasa, Bautista, Criselda, Manalo, Daria L, Gomez, Ma Ricci R, Chu, Maria Yna Joyce V, Miranda, Mary Elizabeth, Kamat, Maya, Rysava, Kristyna, Espineda, Jason, Silo, Eva Angelica V, Aringo, Ariane Mae, Bernales, Rona P, Adonay, Florencio F, Tildesley, Michael J, Marston, Denise A, Jennings, Daisy L, Fooks, Anthony R, Zhu, Wenlong, Meredith, Luke W, Hill, Sarah C, Poplawski, Radoslaw, Gifford, Robert J, Singer, Joshua B, Maturi, Mathew, Mwatondo, Athman, Biek, Roman, and Hampson, Katie

Subjects

whole genome sequencing, dog-mediated rabies, surveillance, MinION, rabies virus, field sequencing, phylogenetic, lyssavirus, nanopore, neglected tropical diseases, 3. Good health, zoonoses

Abstract

Genomic surveillance is an important aspect of contemporary disease management but has yet to be used routinely to monitor endemic disease transmission and control in low- and middle-income countries. Rabies is an almost invariably fatal viral disease that causes a large public health and economic burden in Asia and Africa, despite being entirely vaccine preventable. With policy efforts now directed towards achieving a global goal of zero dog-mediated human rabies deaths by 2030, establishing effective surveillance tools is critical. Genomic data can provide important and unique insights into rabies spread and persistence that can direct control efforts. However, capacity for genomic research in low- and middle-income countries is held back by limited laboratory infrastructure, cost, supply chains and other logistical challenges. Here we present and validate an end-to-end workflow to facilitate affordable whole genome sequencing for rabies surveillance utilising nanopore technology. We used this workflow in Kenya, Tanzania and the Philippines to generate rabies virus genomes in two to three days, reducing costs to approximately £60 per genome. This is over half the cost of metagenomic sequencing previously conducted for Tanzanian samples, which involved exporting samples to the UK and a three- to six-month lag time. Ongoing optimization of workflows are likely to reduce these costs further. We also present tools to support routine whole genome sequencing and interpretation for genomic surveillance. Moreover, combined with training workshops to empower scientists in-country, we show that local sequencing capacity can be readily established and sustainable, negating the common misperception that cutting-edge genomic research can only be conducted in high resource laboratories. More generally, we argue that the capacity to harness genomic data is a game-changer for endemic disease surveillance and should precipitate a new wave of researchers from low- and middle-income countries.

6. Rapid in-country sequencing of whole virus genomes to inform rabies elimination programmes

Author

Brunker, Kirstyn, Jaswant, Gurdeep, Thumbi, S M, Lushasi, Kennedy, Lugelo, Ahmed, Czupryna, Anna M, Ade, Fred, Wambura, Gati, Chuchu, Veronicah, Steenson, Rachel, Ngeleja, Chanasa, Bautista, Criselda, Manalo, Daria L, Gomez, Ma Ricci R, Chu, Maria Yna Joyce V, Miranda, Mary Elizabeth, Kamat, Maya, Rysava, Kristyna, Espineda, Jason, Silo, Eva Angelica V, Aringo, Ariane Mae, Bernales, Rona P, Adonay, Florencio F, Tildesley, Michael J, Marston, Denise A, Jennings, Daisy L, Fooks, Anthony R, Zhu, Wenlong, Meredith, Luke W, Hill, Sarah C, Poplawski, Radoslaw, Gifford, Robert J, Singer, Joshua B, Maturi, Mathew, Mwatondo, Athman, Biek, Roman, and Hampson, Katie

Subjects

Nanopore, Field Sequencing, Phylogenetic, Surveillance, Whole Genome Sequencing, Rabies virus, Zoonoses, Minion, Lyssavirus, Dog-mediated Rabies, 3. Good health, Neglected Tropical Diseases

Abstract

Genomic surveillance is an important aspect of contemporary disease management but has yet to be used routinely to monitor endemic disease transmission and control in low- and middle-income countries. Rabies is an almost invariably fatal viral disease that causes a large public health and economic burden in Asia and Africa, despite being entirely vaccine preventable. With policy efforts now directed towards achieving a global goal of zero dog-mediated human rabies deaths by 2030, establishing effective surveillance tools is critical. Genomic data can provide important and unique insights into rabies spread and persistence that can direct control efforts. However, capacity for genomic research in low- and middle-income countries is held back by limited laboratory infrastructure, cost, supply chains and other logistical challenges. Here we present and validate an end-to-end workflow to facilitate affordable whole genome sequencing for rabies surveillance utilising nanopore technology. We used this workflow in Kenya, Tanzania and the Philippines to generate rabies virus genomes in two to three days, reducing costs to approximately £60 per genome. This is over half the cost of metagenomic sequencing previously conducted for Tanzanian samples, which involved exporting samples to the UK and a three- to six-month lag time. Ongoing optimization of workflows are likely to reduce these costs further. We also present tools to support routine whole genome sequencing and interpretation for genomic surveillance. Moreover, combined with training workshops to empower scientists in-country, we show that local sequencing capacity can be readily established and sustainable, negating the common misperception that cutting-edge genomic research can only be conducted in high resource laboratories. More generally, we argue that the capacity to harness genomic data is a game-changer for endemic disease surveillance and should precipitate a new wave of researchers from low- and middle-income countries.

7. Rapid in-country sequencing of whole virus genomes to inform rabies elimination programmes

Author

Kirstyn Brunker, Gurdeep Jaswant, S.M. Thumbi, Kennedy Lushasi, Ahmed Lugelo, Anna M. Czupryna, Fred Ade, Gati Wambura, Veronicah Chuchu, Rachel Steenson, Chanasa Ngeleja, Criselda Bautista, Daria L. Manalo, Ma. Ricci R. Gomez, Maria Yna Joyce V. Chu, Mary Elizabeth Miranda, Maya Kamat, Kristyna Rysava, Jason Espineda, Eva Angelica V. Silo, Ariane Mae Aringo, Rona P. Bernales, Florencio F. Adonay, Michael J. Tildesley, Denise A. Marston, Daisy L. Jennings, Anthony R. Fooks, Wenlong Zhu, Luke W. Meredith, Sarah C. Hill, Radoslaw Poplawski, Robert J. Gifford, Joshua B. Singer, Mathew Maturi, Athman Mwatondo, Roman Biek, Katie Hampson, Brunker, Kirstyn [0000-0001-9990-6299], Thumbi, S M [0000-0002-5754-0556], Lushasi, Kennedy [0000-0002-2060-4202], Wambura, Gati [0000-0002-3137-2355], Steenson, Rachel [0000-0002-1579-6596], Manalo, Daria L [0000-0001-9290-5146], Chu, Maria Yna Joyce V [0000-0001-6709-2534], Kamat, Maya [0000-0002-7792-2084], Rysava, Kristyna [0000-0002-3475-931X], Tildesley, Michael J [0000-0002-6875-7232], Meredith, Luke W [0000-0002-3802-8290], Gifford, Robert J [0000-0003-4028-9884], Singer, Joshua B [0000-0001-6989-475X], Biek, Roman [0000-0003-3471-5357], Apollo - University of Cambridge Repository, Thumbi, SM [0000-0002-5754-0556], and Fooks, Anthony R [0000-0002-3243-6154]

Subjects

0301 basic medicine, Nanopore, Surveillance, Whole Genome Sequencing, 030231 tropical medicine, Medicine (miscellaneous), Minion, Articles, Method Article, General Biochemistry, Genetics and Molecular Biology, Dog-mediated Rabies, 3. Good health, Field Sequencing, 03 medical and health sciences, Phylogenetic, 030104 developmental biology, 0302 clinical medicine, Rabies virus, Zoonoses, Lyssavirus, Neglected Tropical Diseases

Abstract

Genomic surveillance is an important aspect of contemporary disease management but has yet to be used routinely to monitor endemic disease transmission and control in low- and middle-income countries. Rabies is an almost invariably fatal viral disease that causes a large public health and economic burden in Asia and Africa, despite being entirely vaccine preventable. With policy efforts now directed towards achieving a global goal of zero dog-mediated human rabies deaths by 2030, establishing effective surveillance tools is critical. Genomic data can provide important and unique insights into rabies spread and persistence that can direct control efforts. However, capacity for genomic research in low- and middle-income countries is held back by limited laboratory infrastructure, cost, supply chains and other logistical challenges. Here we present and validate an end-to-end workflow to facilitate affordable whole genome sequencing for rabies surveillance utilising nanopore technology. We used this workflow in Kenya, Tanzania and the Philippines to generate rabies virus genomes in two to three days, reducing costs to approximately £60 per genome. This is over half the cost of metagenomic sequencing previously conducted for Tanzanian samples, which involved exporting samples to the UK and a three- to six-month lag time. Ongoing optimization of workflows are likely to reduce these costs further. We also present tools to support routine whole genome sequencing and interpretation for genomic surveillance. Moreover, combined with training workshops to empower scientists in-country, we show that local sequencing capacity can be readily established and sustainable, negating the common misperception that cutting-edge genomic research can only be conducted in high resource laboratories. More generally, we argue that the capacity to harness genomic data is a game-changer for endemic disease surveillance and should precipitate a new wave of researchers from low- and middle-income countries.

Published

2020