Zobrazeno 1 - 10
of 13
pro vyhledávání: '"Lauren C Liddell"'
Autor:
Lauren C. Liddell, Diana M. Gentry, Rachel Gilbert, Diana Marina, Sofia Massaro Tieze, Michael R. Padgen, Kylie Akiyama, Kyra Keenan, Sharmila Bhattacharya, Sergio R. Santa Maria
Publikováno v:
Astrobiology. 23:648-656
Publikováno v:
Astrobiology. 23:631-636
BioSentinel is the first biological CubeSat designed and developed for deep space. The main objectives of this NASA mission are to assess the effects of deep space radiation on biological systems and to engineer a CubeSat platform that can autonomous
Autor:
Charles Friedericks, Sharmila Bhattacharya, Sergio R. Santa Maria, Macarena Parra, Michael R. Padgen, Aaron Schooley, Lauren C Liddell, Lance Ellingson, Antonio J. Ricco, Ming Tan, Joshua E. Benton, Abraham Rademacher, Diana B. Marina, Robert P. Hanel, Travis Boone, Diana Gentry, Aliyeh Mousavi, Shilpa R. Bhardwaj
Publikováno v:
Astrobiology. 23:637-647
Small satellite technologies, particularly CubeSats, are enabling breakthrough research in space. Over the past 15 years, NASA Ames Research Center has developed and flown half a dozen biological CubeSats in low Earth orbit (LEO) to conduct space bio
Autor:
Sharmila Bhattacharya, Sergio R. Santa Maria, Lauren C Liddell, Diana B. Marina, Sofia Massaro Tieze
Publikováno v:
Astrobiology. 23:617-630
The biological risks of the deep space environment must be elucidated to enable a new era of human exploration and scientific discovery beyond low earth orbit (LEO). There is a paucity of deep space biological missions that will inform us of the dele
Autor:
Ada Kanapskyte, Elizabeth M. Hawkins, Lauren C. Liddell, Shilpa R. Bhardwaj, Diana Gentry, Sergio R. Santa Maria
Publikováno v:
Biosensors, Vol 11, Iss 2, p 38 (2021)
In light of future missions beyond low Earth orbit (LEO) and the potential establishment of bases on the Moon and Mars, the effects of the deep space environment on biology need to be examined in order to develop protective countermeasures. Although
Externí odkaz:
https://doaj.org/article/0a7cc2187e89425ab7b3f4df51be178c
Publikováno v:
Frontiers in Space Technologies. 3
For the last 15 years, small satellites known as CubeSats have been used to investigate the effects of the space environment on biological organisms. All biological CubeSat missions flown to date have performed studies in low Earth orbit (LEO), each
Publikováno v:
Coral Reefs. 39:47-54
The relationship between cnidarians and their micro-algal symbionts is crucial for normal animal function and the formation of coral reefs. We used the sea anemone Exaiptasia pallida (Aiptasia) as a model cnidarian–dinoflagellate system to determin
Autor:
Sergio R, Santa Maria, Diana B, Marina, Sofia, Massaro Tieze, Lauren C, Liddell, Sharmila, Bhattacharya
Publikováno v:
Astrobiology.
The biological risks of the deep space environment must be elucidated to enable a new era of human exploration and scientific discovery beyond low earth orbit (LEO). There is a paucity of deep space biological missions that will inform us of the dele
Publikováno v:
Nucleic Acids Research
RAD52 is a homologous recombination (HR) protein that is conserved from bacteriophage to humans. Simultaneously attenuating expression of both the RAD52 gene, and the HR and tumor suppressor gene, BRCA2, in human cells synergistically reduces HR –
Autor:
Sergio R. Santa Maria, Ada Kanapskyte, Elizabeth M. Hawkins, Shilpa R. Bhardwaj, Diana Gentry, Lauren C Liddell
Publikováno v:
Biosensors
Biosensors, Vol 11, Iss 38, p 38 (2021)
Biosensors, Vol 11, Iss 38, p 38 (2021)
In light of future missions beyond low Earth orbit (LEO) and the potential establishment of bases on the Moon and Mars, the effects of the deep space environment on biology need to be examined in order to develop protective countermeasures. Although