東華大學圖書館 |

Growth In Common Brown Shrimp Crangon Crangon (Caridea, L. 1758). Improving Growth Parameterization in Future Lifecycle Models = = Wachstum der Nordseegarnele Crangon crangon (Caridea, L. 1758). Verbesserung der Wachstumsparametrisierung in zukunftigen Lebenszyklusmodellen.

Record Type:	Electronic resources : Monograph/item
Title/Author:	Growth In Common Brown Shrimp Crangon Crangon (Caridea, L. 1758). Improving Growth Parameterization in Future Lifecycle Models =/
Reminder of title:	Wachstum der Nordseegarnele Crangon crangon (Caridea, L. 1758). Verbesserung der Wachstumsparametrisierung in zukunftigen Lebenszyklusmodellen.
Author:	Saathoff, Merten.
Published:	Ann Arbor : ProQuest Dissertations & Theses, : 2023,
Description:	159 p.
Notes:	Source: Dissertations Abstracts International, Volume: 85-06, Section: B.
Contained By:	Dissertations Abstracts International85-06B.
Subject:	Plankton. -
Online resource:	https://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=30736621
ISBN:	9798381023572

Growth In Common Brown Shrimp Crangon Crangon (Caridea, L. 1758). Improving Growth Parameterization in Future Lifecycle Models = = Wachstum der Nordseegarnele Crangon crangon (Caridea, L. 1758). Verbesserung der Wachstumsparametrisierung in zukunftigen Lebenszyklusmodellen.
Saathoff, Merten.

Growth In Common Brown Shrimp Crangon Crangon (Caridea, L. 1758). Improving Growth Parameterization in Future Lifecycle Models =Wachstum der Nordseegarnele Crangon crangon (Caridea, L. 1758). Verbesserung der Wachstumsparametrisierung in zukunftigen Lebenszyklusmodellen. - Ann Arbor : ProQuest Dissertations & Theses, 2023 - 159 p.

Source: Dissertations Abstracts International, Volume: 85-06, Section: B.

Thesis (Ph.D.)--Universitaet Hamburg (Germany), 2023.

This item must not be sold to any third party vendors.

The common brown shrimp (Crangon crangon) is a species of high economical and ecological value in the southern North Sea ecosystem. Its presence in almost all areas, not only makes C. crangona key species by being both predator and prey for a wide variety of other ecosystem inhabitants, but also forms the basis of a 500-vessel strong fishery that lands up to 40,000 tons annually, generating revenues of around 120 million euros. Due to the lack of moult enduring hard structures, a year-round lasting spawning period and the short-lived nature of the species, age determination in the common brown shrimp is nearly impossible. Hence, common-, agebased management approaches, such as the maximum sustainable yield (MSY) were found not applicable for the common brown shrimp stock. Aiming at the certification of the fishery by the marine stewardship council (MSC), in 2016 a self-management plan was introduced, in which measures alternative to a quota were set. The potential benefits and effects of these measures were calculated using a species-specific yield per recruit model, parameterized with growth data from decades of growth research on the species. The results of this model and the conclusions drawn for the management are highly influenced by the given growth input. Although the species, due to its extensive use, has been the subject of growth research since the late 1940th, to date questions remain about the factors influencing the growth in common brown shrimp. The aim of this thesis is to address some of these questions, and to further improve the parameterization in future growth calculations.Crucial for the survival and growth of common brown shrimp is known to be food availability. At the same time, parts of the common brown shrimp population are-, depending on season, known to be exposed to prolonged periods of starvation. Despite their omnivorous feeding behaviour and the otherwise very productive ecosystem, in winter up to 80 percent of the population can be in a starving condition. The response of C. crangon to starvation has studied previously, but no study has been conducted in which the animals were starved for long periods and then fed again. Manuscript 1addresses the influence of prolonged food deprivation followed by re-feeding on the growth of the common brown shrimp. In laboratory experiments, animals were deprived of food for different periods of time and were re-fed thereafter. Subsequently, the moulting interval and the growth increment, determined individually, were compared with a control group that was fed ad libitum for the entire trial period. Food deprivation significantly increased the time between two successive moults and reduced the growth increment into a negative range. Shrinkage had previously been observed in the common brown shrimp occasionally but was first observed systematically in manuscript 1. In addition to the prolongation of the moulting interval during food deprivation, which was previously considered to mainly be a function of temperature and size, shrinkage was identified as a physiological necessity to compensate for the dry mass lost during the starvation period. The results from manuscript 1, combined with the observations of other authors that especially in winter up to 80 % of the population show a condition that indicate prolonged starvation, could be used to adjust growth predictions of the stock in winter. Since egg deposition and egg laying are linked to a moult event, the delayed moult due to starvation could affect the reproductive cycle of starving females.

ISBN: 9798381023572Subjects--Topical Terms:

1299572
Plankton.

Growth In Common Brown Shrimp Crangon Crangon (Caridea, L. 1758). Improving Growth Parameterization in Future Lifecycle Models = = Wachstum der Nordseegarnele Crangon crangon (Caridea, L. 1758). Verbesserung der Wachstumsparametrisierung in zukunftigen Lebenszyklusmodellen.
LDR:09399nmm a2200361 4500 001 2393407
005 20240315085559.5
006 m o d
007 cr#unu||||||||
008 251215s2023 ||||||||||||||||| ||eng d
020 $a 9798381023572
035 $a (MiAaPQ)AAI30736621
035 $a (MiAaPQ)Hamburg10431
035 $a AAI30736621
040 $a MiAaPQ $c MiAaPQ
100 1 $a Saathoff, Merten. $3 3762868
245 1 0 $a Growth In Common Brown Shrimp Crangon Crangon (Caridea, L. 1758). Improving Growth Parameterization in Future Lifecycle Models = $b Wachstum der Nordseegarnele Crangon crangon (Caridea, L. 1758). Verbesserung der Wachstumsparametrisierung in zukunftigen Lebenszyklusmodellen.
260 1 $a Ann Arbor : $b ProQuest Dissertations & Theses, $c 2023
300 $a 159 p.
500 $a Source: Dissertations Abstracts International, Volume: 85-06, Section: B.
500 $a Advisor: Temming, Axel;Hufnagl, Marc.
502 $a Thesis (Ph.D.)--Universitaet Hamburg (Germany), 2023.
506 $a This item must not be sold to any third party vendors.
520 $a The common brown shrimp (Crangon crangon) is a species of high economical and ecological value in the southern North Sea ecosystem. Its presence in almost all areas, not only makes C. crangona key species by being both predator and prey for a wide variety of other ecosystem inhabitants, but also forms the basis of a 500-vessel strong fishery that lands up to 40,000 tons annually, generating revenues of around 120 million euros. Due to the lack of moult enduring hard structures, a year-round lasting spawning period and the short-lived nature of the species, age determination in the common brown shrimp is nearly impossible. Hence, common-, agebased management approaches, such as the maximum sustainable yield (MSY) were found not applicable for the common brown shrimp stock. Aiming at the certification of the fishery by the marine stewardship council (MSC), in 2016 a self-management plan was introduced, in which measures alternative to a quota were set. The potential benefits and effects of these measures were calculated using a species-specific yield per recruit model, parameterized with growth data from decades of growth research on the species. The results of this model and the conclusions drawn for the management are highly influenced by the given growth input. Although the species, due to its extensive use, has been the subject of growth research since the late 1940th, to date questions remain about the factors influencing the growth in common brown shrimp. The aim of this thesis is to address some of these questions, and to further improve the parameterization in future growth calculations.Crucial for the survival and growth of common brown shrimp is known to be food availability. At the same time, parts of the common brown shrimp population are-, depending on season, known to be exposed to prolonged periods of starvation. Despite their omnivorous feeding behaviour and the otherwise very productive ecosystem, in winter up to 80 percent of the population can be in a starving condition. The response of C. crangon to starvation has studied previously, but no study has been conducted in which the animals were starved for long periods and then fed again. Manuscript 1addresses the influence of prolonged food deprivation followed by re-feeding on the growth of the common brown shrimp. In laboratory experiments, animals were deprived of food for different periods of time and were re-fed thereafter. Subsequently, the moulting interval and the growth increment, determined individually, were compared with a control group that was fed ad libitum for the entire trial period. Food deprivation significantly increased the time between two successive moults and reduced the growth increment into a negative range. Shrinkage had previously been observed in the common brown shrimp occasionally but was first observed systematically in manuscript 1. In addition to the prolongation of the moulting interval during food deprivation, which was previously considered to mainly be a function of temperature and size, shrinkage was identified as a physiological necessity to compensate for the dry mass lost during the starvation period. The results from manuscript 1, combined with the observations of other authors that especially in winter up to 80 % of the population show a condition that indicate prolonged starvation, could be used to adjust growth predictions of the stock in winter. Since egg deposition and egg laying are linked to a moult event, the delayed moult due to starvation could affect the reproductive cycle of starving females.
520 $a Die Nordseegarnele (Crangon crangon) ist eine Art von hohem wirtschaftlichem und okologischem Wert im Okosystem der sudlichen Nordsee. Ihr Vorkommen in fast allen Gebieten macht C. crangon nicht nur zu einer Schlusselart, da sie sowohl Rauber als auch Beute fur eine Vielzahl anderer Okosystembewohner darstellt, sondern bildet auch die Grundlage fur eine ca. 500 Fischereifahrzeuge umfassende Fischerei, die jahrlich bis zu 40.000 Tonnen Garnelen anlandet und damit Einnahmen in Hohe von rund 120 Millionen Euro erzielt. Aufgrund des Fehlens die Hautung uberdauernder Hartstrukturen, einer ganzjahrig andauernden Laichzeit sowie der Kurzlebigkeit der Art, ist eine Altersbestimmung bei der Nordseegarnele nahezu unmoglich. Herkommliche, altersbasierte Bewirtschaftungsansatze wie der Maximum Sustainable Yield (MSY) haben sich daher fur den Nordseegarnelenbestand als nicht anwendbar erwiesen. Im Zuge der Zertifizierung der Fischerei durch den Marine Stewardship Council (MSC), wurde 2016 ein sogenannter Selbstmanagementplan impliziert, in dem alternative Masnahmen zu einer Quote festgelegt wurden. Der potenzielle Nutzen und die Auswirkungen dieser Masnahmen wurden mithilfe eines artspezifischen Yield per Recruits Modells berechnet, welches mit Wachstumsdaten aus jahrzehntelanger Wachstumsforschung an der Art parametrisiert wurde. Die Ergebnisse dieses Modells und die daraus gezogenen Schlussfolgerungen fur eine mogliche Bewirtschaftungsstrategie des Bestandes, werden in hohem Mase durch den gegebenen Wachstumsinput beeinflusst. Obwohl die C. crangonaufgrund der extensiven Nutzung seit den spaten 1940er Jahren Gegenstand intensiver wissenschaftlicher Untersuchungen ist, bleiben bis heute einige Fragen zum Wachstum der Art unbeantwortet. Ziel dieser Arbeit ist es, einige dieser Fragen zu klaren und die Parametrisierung bei zukunftigen Wachstumsberechnungen so zu verbessern.Entscheidend fur das Uberleben und Wachstum der Nordseegarnele ist bekanntermasen die Verfugbarkeit von Nahrung. Gleichzeitig ist bekannt, dass Teile der Nordseegarnelenpopulation - je nach Jahreszeit - langeren Hungerperioden ausgesetzt sind. Trotz ihres omnivoren Fressverhaltens und des ansonsten sehr produktiven Okosystems, in dem sich die Art aufhalt, konnen sich im Winter bis zu 80 Prozent der Population in einem Zustand befinden, welcher auf die Uberdauerung langerer Hungerperioden hindeutet. Die Reaktion von C. crangon auf Hunger wurde bereits an anderer Stelle untersucht, jedoch wurde bis heute keine Studie durchgefuhrt, bei der die Tiere uber einen langeren Zeitraum hungerten und anschliesend wieder gefuttert wurden, was dem Ende einer im Feld auftretenden Nahrungsknappheit am nachsten kommen wurde. Manuskript 1befasst sich mit dem Einfluss von langerem Nahrungsentzug und anschliesender Wiederfutterung auf das Wachstum der Nordseegarnele. In Laborexperimenten wurde den Tieren fur unterschiedlich andauernde Zeitraume die Nahrung entzogen und anschliesend wurden die Tiere erneut ad-libitum gefuttert. Anschliesend wurden das Hautungsintervall und der Wachstumszuwachs, welche individuell bestimmt wurden, mit einer Kontrollgruppe verglichen, die wahrend des gesamten Versuchszeitraums ad-libitum gefuttert wurde. Durch den Nahrungsentzug verlangerte sich die Zeit zwischen zwei aufeinander folgenden Hautungen erheblich und der Langenzuwachs sank in den negativen Bereich. Schrumpfen war schon fruher gelegentlich bei der Nordseegarnele beobachtet worden, wurde aber in Manuskript 1 erstmals systematisch beobachtet. Neben der Verlangerung des Hautungsintervalls-, welches bisher hauptsachlich als Funktion von Temperatur und Grose angesehen wurde, konnte das Schrumpfen als physiologische Notwendigkeit identifiziert werden, um fur die wahrend des Nahrungsentzuges verlorene Trockenmasse zu kompensieren. Die Ergebnisse aus Manuskript 1 in Verbindung mit den Beobachtungen anderer Autoren, dass insbesondere im Winter bis zu 80 % der Population einen Zustand aufweisen, der auf eine anhaltende Nahrungsknappheit hindeutet, konnten zur Anpassung der Wachstumsprognosen fur den Bestand im Winter herangezogen werden. Da die Eiablage eng mit der Hautung der Tiere verknupft ist, konnte die verzogerte Hautung den Fortpflanzungszyklus hungernder Weibchen beeintrachtigen. Verringertes Wachstum wahrend einer Nahrungsknappheit und insbesondere das Schrumpfen konnten die Berechnung potenzieller Fangmengen in der Fruhjahrsfischerei nach einem Winter mit Nahrungsknappheit verringern.
590 $a School code: 0661.
650 4 $a Plankton. $3 1299572
650 4 $a Food. $3 551593
650 4 $a Mortality. $3 533218
650 4 $a Seasons. $3 523975
650 4 $a Shellfish. $3 2147548
650 4 $a Winter. $3 603950
650 4 $a Crustaceans. $3 3548330
650 4 $a Eggs. $3 865987
650 4 $a Fishing. $3 566322
650 4 $a Respiration. $3 610890
650 4 $a Summer. $3 800184
650 4 $a Water temperature. $3 2131767
650 4 $a Aquatic sciences. $3 3174300
650 4 $a Biological oceanography. $3 2122748
650 4 $a Microbiology. $3 536250
690 $a 0792
690 $a 0416
690 $a 0410
710 2 $a Universitaet Hamburg (Germany). $3 3697674
773 0 $t Dissertations Abstracts International $g 85-06B.
790 $a 0661
791 $a Ph.D.
792 $a 2023
793 $a English
856 4 0 $u https://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=30736621