Home Print this page Email this page Small font sizeDefault font sizeIncrease font size
Users Online: 132
Home | About us | Editorial board | Search | Ahead of print | Current issue | Archives | Submit article | Instructions | Subscribe | Contacts | Login 
     

    Article Cited by others

DISPATCHES

The basic rules and methods of mosquito rearing (Aedes aegypti)

Imam Hashmat, Zarnigar, Sofi Ghulamuddin, Aziz Seikh

Year : 2014| Volume: 4| Issue : 1 | Page no: 53-55

   This article has been cited by
 
1 Field evaluation of WALS truck-mounted A1 super duty mist sprayer® with VectoBac® WDG against Aedes aegypti (Diptera:Culicidae) populations in Manatee County, Florida
Katie Katie Williams, Samantha Ramirez, Christopher R. Lesser
SN Applied Sciences. 2022; 4(2)
[Pubmed]  [Google Scholar] [DOI]
2 Contact in-vivo larvicidal toxicity and histological studies of Indian herb essential oils loaded niosomes against Aedes aegypti and Culex quinquefasciatus (Diptera: Culicidae)
Jose Gnanaleela Aswin Jeno,Soosaimanickam Maria Packiam,Ekambaram Nakkeeran
International Journal of Tropical Insect Science. 2021;
[Pubmed]  [Google Scholar] [DOI]
3 Better eggs today than psocids tomorrow: Aedes aegypti (Diptera: Culicidae) eggs exposed to Liposcelis sp. (Psocodea: Liposcelididae) has reduced hatching rates
Lidia Moura,Barbara Lepretti de Nadai,Maria Eduarda Yumi Oyamaguti,Juliano J. Corbi
Journal of Asia-Pacific Entomology. 2021;
[Pubmed]  [Google Scholar] [DOI]
4 Green synthesis of carbon dot silver nanohybrids from fruits and vegetable’s peel waste: Applications as potent mosquito larvicide
Prasanta K. Raul,Prathama Santra,Diganta Goswami,Varun Tyagi,C. Yellappa,Vanlalh mauka,Rashmi R. Devi,P. Chattopadhyay,Radha V. Jayaram,Sanjai K. Dwivedi
Current Research in Green and Sustainable Chemistry. 2021; : 100158
[Pubmed]  [Google Scholar] [DOI]
5 Cryoprotectant toxicity and hypothermic sensitivity among Anopheles larvae
Jenny E. Nesbitt,Anisa Swei,Catherine Hunt,Ellen M. Dotson,Mehmet Toner,Rebecca D. Sandlin
Cryobiology. 2021; 99: 106
[Pubmed]  [Google Scholar] [DOI]
6 Towards a method for cryopreservation of mosquito vectors of human pathogens
Emily N. Gallichotte,Karen M. Dobos,Gregory D. Ebel,Mary Hagedorn,Jason L. Rasgon,Jason H. Richardson,Timothy T. Stedman,Jennifer P. Barfield
Cryobiology. 2021; 99: 1
[Pubmed]  [Google Scholar] [DOI]
7 Implications of diet on mosquito life history traits and pathogen transmission
Laura Carvajal-Lago,María José Ruiz-López,Jordi Figuerola,Josué Martínez-de la Puente
Environmental Research. 2021; 195: 110893
[Pubmed]  [Google Scholar] [DOI]
8 Insights into factors sustaining persistence of high malaria transmission in forested areas of sub-Saharan Africa: the case of Mvoua, South Cameroon
Dominique Mieguim Ngninpogni,Cyrille Ndo,Patrick Ntonga Akono,Anicet Nguemo,Amine Nguepi,Danale Rosine Metitsi,Jeannette Tombi,Parfait Awono-Ambene,Charles Félix Bilong Bilong
Parasites & Vectors. 2021; 14(1)
[Pubmed]  [Google Scholar] [DOI]
9 CONTROL DE Aedes aegypti (DIPTERA: CULICIDAE) MEDIANTE ACTINOBACTERIAS FORMADORAS DE BIOPELÍCULAS.
Miguel Constante Bobadilla Alvarez,Edwin Julio Palomino Cadenas
Acta Biológica Colombiana. 2021; 26(3): 423
[Pubmed]  [Google Scholar] [DOI]
10 Multi-Omic Analysis of Symbiotic Bacteria Associated With Aedes aegypti Breeding Sites
Katherine D. Mosquera,Luis E. Martinez Villegas,Sacha J. Pidot,Chinhda Sharif,Sven Klimpel,Timothy P. Stinear,Luciano A. Moreira,Nicholas J. Tobias,Marcelo G. Lorenzo
Frontiers in Microbiology. 2021; 12
[Pubmed]  [Google Scholar] [DOI]
11 Semi-field life-table studies of Aedes albopictus (Diptera: Culicidae) in Guangzhou, China
Dizi Yang,Yulan He,Weigui Ni,Qi Lai,Yonghong Yang,Jiayan Xie,Tianrenzheng Zhu,Guofa Zhou,Xueli Zheng,Jiang-Shiou Hwang
PLOS ONE. 2020; 15(3): e0229829
[Pubmed]  [Google Scholar] [DOI]
12 Collection and Rearing of Container Mosquitoes and a 24-h Addition to the CDC Bottle Bioassay
Casey Parker,Karen Poh
Journal of Insect Science. 2020; 20(6)
[Pubmed]  [Google Scholar] [DOI]
13 Distribution and Frequency of the kdr Mutation V410L in Natural Populations of Aedes aegypti (L.) (Diptera: Culicidae) From Eastern and Southern Mexico
Olga K Villanueva-Segura,Kevin A Ontiveros-Zapata,Beatriz Lopez-Monroy,Gustavo Ponce-Garcia,Selene M Gutierrez-Rodriguez,Jesus A Davila-Barboza,Esteban de J Mora-Jasso,Adriana E Flores,David Severson
Journal of Medical Entomology. 2020; 57(1): 218
[Pubmed]  [Google Scholar] [DOI]
14 Inhibition of the growth and development of mosquito larvae of Culex pipiens L. (Diptera: Culicidae) treated with extract from flower of Matricaria chamomilla (Asteraceae)
Fahd A. Al-Mekhlafi,Nael Abutaha,Ahmed M. Al-Malki,Muhammad Al-Wadaan
Entomological Research. 2020; 50(3): 138
[Pubmed]  [Google Scholar] [DOI]
15 Accelerating the Morphogenetic Cycle of the Viral Vector Aedes aegypti Larvae for Faster Larvicidal Bioassays
José Domingos Fontana,Rafael Lopes Ferreira,Tatiana Zuccolotto,Cibelle de Borba Dallagassa,Leonardo Pellizzari Wielewski,Barbara Maria Santano Chalcoski,Mario Antonio Navarro da Silva,Vinicius Sobrinho Richardi,Jonas Golart,Cynara de Melo Rodovalho
BioMed Research International. 2020; 2020: 1
[Pubmed]  [Google Scholar] [DOI]
16 Novel bioadhesive polycarbophil-based liquid crystal systems containing Melaleuca alternifolia oil as potential repellents against Aedes aegypti
Jonatas L. Duarte,Thais C. Taira,Leonardo Delello Di Filippo,Bruno Fonseca-Santos,Mara Cristina Pinto,Marlus Chorilli
Journal of Molecular Liquids. 2020; 314: 113626
[Pubmed]  [Google Scholar] [DOI]
17 Compatibility between Leptolegnia chapmanii and diflubenzuron and neem oil for the control of Aedes aegypti
Manuel E. Rueda Páramo,Marianel Falvo,Juan García,Claudia C. López Lastra
Revista Argentina de Microbiología. 2020; 52(3): 240
[Pubmed]  [Google Scholar] [DOI]
18 Acute and chronic exposure of the holometabolous life cycle of Aedes aegypti L. to emerging contaminants naproxen and propylparaben
Mayer L. Calma,Paul Mark B. Medina
Environmental Pollution. 2020; 266: 115275
[Pubmed]  [Google Scholar] [DOI]
19 The efficiency of a new automated mosquito larval counter and its impact on larval survival
W. Mamai,H. Maiga,M. Gárdos,P. Bán,N. S. Bimbilé Somda,A. Konczal,T. Wallner,A. Parker,F. Balestrino,H. Yamada,J. R. L. Gilles,J. Bouyer
Scientific Reports. 2019; 9(1)
[Pubmed]  [Google Scholar] [DOI]
20 Mosquito bite prevention through graphene barrier layers
Cintia J. Castilho,Dong Li,Muchun Liu,Yue Liu,Huajian Gao,Robert H. Hurt
Proceedings of the National Academy of Sciences. 2019; 116(37): 18304
[Pubmed]  [Google Scholar] [DOI]
21 Dispersal and survival of radio-sterilised male Aedes albopictus Skuse (Diptera: Culicidae) and estimation of the wild populations in view of an sterile insect technique programme in Pointe des Lascars, Mauritius
Diana Pillay Iyaloo,David Damiens,Sunita Facknath,Khouaildi Bin Elahee,Ambicadutt Bheecarry
International Journal of Tropical Insect Science. 2019;
[Pubmed]  [Google Scholar] [DOI]
22 The abundance and larval performance of Aedes phoeniciae in supralittoral rock-pools
Sahar Rosenfeld,Leon Blaustein,Jamie Kneitel,Claire Duchet,Rael Horwitz,Olga Rybak,Antonina Polevikov,Eyal Rahav
Hydrobiologia. 2019; 846(1): 181
[Pubmed]  [Google Scholar] [DOI]
23 Microorganism-Based Larval Diets Affect Mosquito Development, Size and Nutritional Reserves in the Yellow Fever Mosquito Aedes aegypti (Diptera: Culicidae)
Raquel Santos Souza,Flavia Virginio,Thaís Irene Souza Riback,Lincoln Suesdek,José Bonomi Barufi,Fernando Ariel Genta
Frontiers in Physiology. 2019; 10
[Pubmed]  [Google Scholar] [DOI]
24 Aedes albopictus Adult Medium Mass Rearing for SIT Program Development
David Damiens,Lucie Marquereau,Cyrille Lebon,Gilbert Le Goff,Benjamin Gaudillat,Nausicaa Habchi-Hanriot,Louis-Clément Gouagna
Insects. 2019; 10(8): 246
[Pubmed]  [Google Scholar] [DOI]
25 Habitat Characteristics For Immature Stages of Aedes aegypti In Zanzibar City, Tanzania
Fatma Saleh,Jovin Kitau,Flemming Konradsen,Michael Alifrangis,Chia-Hsien Lin,Salim Juma,Salum Seif Mchenga,Thabit Saadaty,Karin Linda Schiøler
Journal of the American Mosquito Control Association. 2018; 34(3): 190
[Pubmed]  [Google Scholar] [DOI]
26 Erythromycin Exposure Disrupts the Life Cycle Stages of Aedes aegypti L. (Diptera: Culicidae)
Mayer L. Calma,Joannes Luke B. Asis,Paul Mark B. Medina
Water, Air, & Soil Pollution. 2018; 229(5)
[Pubmed]  [Google Scholar] [DOI]
27 Crystal structure of a novel Kunitz type inhibitor, alocasin with anti-Aedes aegypti activity targeting midgut proteases
Senthilvadivel Vajravijayan,Sergei Pletnev,Vladimir Z Pletnev,Narayanasamy Nandhagopal,Krishnasamy Gunasekaran
Pest Management Science. 2018;
[Pubmed]  [Google Scholar] [DOI]
28 Do avian malaria parasites reduce vector longevity?
Josué Martínez-de la Puente,Rafael Gutiérrez-López,Jordi Figuerola
Current Opinion in Insect Science. 2018; 28: 113
[Pubmed]  [Google Scholar] [DOI]
29 Validation of the species Xiphophorus maculatus for biological control of Aedes aegypty by comparing its larvae-eating potential with Poecilia reticulata
Edimar Olegário de Campos Júnior,Carolina Fabiano Silva,Cleibe Rossi da Silva,Boscolli Barbosa Pereira,Evelyn Siqueira Caixeta,Márcia Beatriz Cardoso de Paula,Juliana Junqueira da Silva,Alessandro Ambrósio dos Reis,Felipe Cunha,Amaral Alves de Souza
Biological Control. 2017;
[Pubmed]  [Google Scholar] [DOI]

 

Read this article