Atnaujinkite slapukų nuostatas

El. knyga: Cardiovascular Development

Volume editor , Series edited by (Icahn School of Medicine, Mount Sinai, USA)
Kitos knygos pagal šią temą:
Cardiovascular DevelopmentDidesnis paveikslėlis
Kitos knygos pagal šią temą:

DRM apribojimai

  • Kopijuoti:

    neleidžiama

  • Spausdinti:

    neleidžiama

  • El. knygos naudojimas:

    Skaitmeninių teisių valdymas (DRM)
    Leidykla pateikė šią knygą šifruota forma, o tai reiškia, kad norint ją atrakinti ir perskaityti reikia įdiegti nemokamą programinę įrangą. Norint skaityti šią el. knygą, turite susikurti Adobe ID . Daugiau informacijos  čia. El. knygą galima atsisiųsti į 6 įrenginius (vienas vartotojas su tuo pačiu Adobe ID).

    Reikalinga programinė įranga
    Norint skaityti šią el. knygą mobiliajame įrenginyje (telefone ar planšetiniame kompiuteryje), turite įdiegti šią nemokamą programėlę: PocketBook Reader (iOS / Android)

    Norint skaityti šią el. knygą asmeniniame arba „Mac“ kompiuteryje, Jums reikalinga  Adobe Digital Editions “ (tai nemokama programa, specialiai sukurta el. knygoms. Tai nėra tas pats, kas „Adobe Reader“, kurią tikriausiai jau turite savo kompiuteryje.)

    Negalite skaityti šios el. knygos naudodami „Amazon Kindle“.

In 1993, Rolf Bodmer described a gene he named tinman that was required for the formation of the dorsal aorta of the fly. Flies without a functional tinman gene had no heart. Quickly, mammalian counterparts of the tinman gene were identified and found to be expressed by early cardiomyogenic precursors and by cardiomyocytes throughout heart development. Since then, significant progress has been made in the understanding of molecular and genetic determinants of heart formation. An ever growing number of genes have been identified that are required for cardiogenesis, as evidenced by severe abnormalities in cardiac development produced by inactivation in the mouse or inhibition of gene function in other model organisms.

Cardiovascular Development covers some of the latest research in the study of heart formation. Volume Editor Rolf Bodmer has assembled a world-class list of contributors whose research uses a variety of animal models and whose findings are certain to enhance our understanding of this exciting field.

* Ties together the development of heart morphology and conduction system
* The latest developments in vertebrate and invertebrate genetic model systems
* Technological advancements in cardiovascular science

In 1993, Rolf Bodmer described a gene he named tinman that was required for the formation of the dorsal aorta of the fly. Flies without a functional tinman gene had no heart. Quickly, mammalian counterparts of the tinman gene were identified and found to be expressed by early cardiomyogenic precursors and by cardiomyocytes throughout heart development. Since then, significant progress has been made in the understanding of molecular and genetic determinants of heart formation. An ever growing number of genes have been identified that are required for cardiogenesis, as evidenced by severe abnormalities in cardiac development produced by inactivation in the mouse or inhibition of gene function in other model organisms.

Cardiovascular Development covers some of the latest research in the study of heart formation. Volume Editor Rolf Bodmer has assembled a world-class list of contributors whose research uses a variety of animal models and whose findings are certain to enhance our understanding of this exciting field.

* Ties together the development of heart morphology and conduction system
* The latest developments in vertebrate and invertebrate genetic model systems
* Technological advancements in cardiovascular science

Daugiau informacijos

The latest technological advancements in understanding the development of cardiovascular systems
1. Heart Development in Drosophila
2. Morphogenesis of the Vertebrate Heart
3. Heart Development and T-box Transcription Factors: Lessons from Avian Embryos
4. Transcriptional Control of Cardiac Boundary Formation
5. Signaling Pathways in Embryonic Heart Induction
6. Islet1 Progenitors in Developing and Postnatal Heart
7. Role of MicroRNAs in Cardiovascular Biology
8. Divergent Roles of Hedgehog and Fibroblast Growth Factor Signaling in Left-Right Development
9. Development of the conduction system: Picking up the pace
10. Transcriptional Control of the Cardiac Conduction System
11. Genetic dissection of hematopoiesis using Drosophila as a model system
12. Vascular Development in the Zebrafish
13. Development and function of the epicardium
14. Genetics of transcription factor mutations
15. Human genetics of congenital heart disease
Paul M. Wassarman, the Series Editor of CTDB since 2007, is Professor in the Dept. Developmental and Regenerative Biology at the Icahn School of Medicine at Mount Sinai in New York City. He received a Ph.D. in biochemistry from Brandeis University where he carried out thesis research in the Graduate Dept. Biochemistry with Professor Nathan O. Kaplan. In 1967 Wassarman joined the Division of Structural Studies at the MRC, Laboratory of Molecular Biology in Cambridge, England as a Helen Hay Whitney Foundation Fellow with Sir John C. Kendrew. In 1972 he joined the faculty of the Dept. Biological Chemistry at Harvard Medical School and in 1986 moved to the Roche Institute of Molecular Biology where he was Chair of the Dept. Cell and Developmental Biology and Adjunct Professor in the Dept. Cell Biology, New York University School of Medicine. In 1996 he moved to the Icahn School of Medicine at Mount Sinai where he was the Lillian and Henry M. Stratton Professorial Chair of the Dept. Molecular, Cell, and Developmental Biology. Wassarman has published more than 200 research papers and reviews, dealing primarily with mammalian oogenesis, fertilization, and early embryogenesis.
Daugiau apie elektronines knygas Daugiau apie elektronines knygas
Pastovi nuoroda: https://www.kriso.lt/db/97800805543892e.html
Raktažodžiai: