Biometric conversion factors as a unifying platform for comparative assessment of invasive freshwater bivalves

Neil E. Coughlan; Eoghan M. Cunningham; Ross N. Cuthbert; Patrick W.S. Joyce; Pedro Anastácio; Filipe Banha; Nicolás Bonel; Stephanie J. Bradbeer; Elizabeta Briski; Vince L. Butitta; Zuzana Čadková; Jaimie T.A. Dick; Karel Douda; Lawrence E. Eagling; Noé Ferreira-Rodríguez; Leandro A. Hünicken; Mattias L. Johansson; Louise Kregting; Anna Maria Labecka; Deliang Li; Florencia Liquin; Jonathan Marescaux; Todd J. Morris; Patrycja Nowakowska; Małgorzata Ożgo; Esteban M. Paolucci; Miguel A. Peribáñez; Nicoletta Riccardi; Emily R.C. Smith; Michael J. Spear; Gregor T. Steffen; Jeremy S. Tiemann; Maria Urbańska; Karine Van Doninck; Martin Vastrade; Gina Y.W. Vong; Brygida Wawrzyniak-Wydrowska; Zhiqiang Xia; Cong Zeng; Aibin Zhan; Francisco Sylvester

doi:10.1111/1365-2664.13941

Biometric conversion factors as a unifying platform for comparative assessment of invasive freshwater bivalves

Neil E. Coughlan
, Eoghan M. Cunningham
, Ross N. Cuthbert
, Patrick W.S. Joyce
, Pedro Anastácio
, Filipe Banha
, Nicolás Bonel
, Stephanie J. Bradbeer
, Elizabeta Briski
, Vince L. Butitta
, Zuzana Čadková
, Jaimie T.A. Dick
, Karel Douda
, Lawrence E. Eagling
, Noé Ferreira-Rodríguez
, Leandro A. Hünicken
, Mattias L. Johansson
, Louise Kregting
, Anna Maria Labecka
, Deliang Li

Florencia Liquin, Jonathan Marescaux, Todd J. Morris, Patrycja Nowakowska, Małgorzata Ożgo, Esteban M. Paolucci, Miguel A. Peribáñez, Nicoletta Riccardi, Emily R.C. Smith, Michael J. Spear, Gregor T. Steffen, Jeremy S. Tiemann, Maria Urbańska, Karine Van Doninck, Martin Vastrade, Gina Y.W. Vong, Brygida Wawrzyniak-Wydrowska, Zhiqiang Xia, Cong Zeng, Aibin Zhan, Francisco Sylvester

School of Biological, Earth and Environmental Sciences

Queen's University Belfast
Helmholtz Centre for Ocean Research Kiel
University of Évora
Centro de Recursos Naturales Renovables de la Zona Semiárida
Université de Montpellier
University of Leeds
University of Wisconsin-Madison
Czech University of Life Sciences Prague
University of Vigo
Museo Argentino de Ciencias Naturales Bernardino Rivadavia
Consejo Nacional de Investigaciones Científicas y Técnicas
University of North Georgia
Jagiellonian University in Kraków
Hunan Agricultural University
Universidad Nacional de Salta
E-BIOM SA
Universite de Namur
Fisheries and Oceans Canada
University of Gdańsk
Kazimierz Wielki University
University of Zaragoza
National Research Council of Italy
University College London
University of Illinois at Urbana-Champaign
Poznań University of Life Sciences
University of Szczecin
University of Windsor
Shanghai Jiao Tong University
CAS - Research Center for Eco-Environmental Sciences
University of Chinese Academy of Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Invasive bivalves continue to spread and negatively impact freshwater ecosystems worldwide. As different metrics for body size and biomass are frequently used within the literature to standardise bivalve-related ecological impacts (e.g. respiration and filtration rates), the lack of broadly applicable conversion equations currently hinders reliable comparison across bivalve populations. To facilitate improved comparative assessment among studies originating from disparate geographical locations, we report body size and biomass conversion equations for six invasive freshwater bivalves (or species complex members) worldwide: Corbicula fluminea, C. largillierti, Dreissena bugensis, D. polymorpha, Limnoperna fortunei and Sinanodonta woodiana, and tested the reliability (i.e. precision and accuracy) of these equations. Body size (length, width and height) and biomass metrics of living-weight (LW), wet-weight (WW), dry-weight (DW), dry shell-weight (SW), shell free dry-weight (SFDW) and ash-free dry-weight (AFDW) were collected from a total of 44 bivalve populations located in Asia, the Americas and Europe. Relationships between body size and individual biomass metrics, as well as proportional weight-to-weight conversion factors, were determined. For most species, although inherent variation existed between sampled populations, body size directional measurements were found to be good predictors of all biomass metrics (e.g. length to LW, WW, SW or DW: R² = 0.82–0.96), with moderate to high accuracy for mean absolute error (MAE): ±9.14%–24.19%. Similarly, narrow 95% confidence limits and low MAE were observed for most proportional biomass relationships, indicating high reliability for the calculated conversion factors (e.g. LW to AFDW; CI range: 0.7–2.0, MAE: ±0.7%–2.0%). Synthesis and applications. Our derived biomass prediction equations can be used to rapidly estimate the biologically active biomass of the assessed species, based on simpler biomass or body size measurements for a wide range of situations globally. This allows for the calculation of approximate average indicators that, when combined with density data, can be used to estimate biomass per geographical unit-area and contribute to quantification of population-level effects. These general equations will support meta-analyses, and allow for comparative assessment of historic and contemporary data. Overall, these equations will enable conservation managers to better understand and predict ecological impacts of these bivalves.

Original language	English
Pages (from-to)	1945-1956
Number of pages	12
Journal	Journal of Applied Ecology
Volume	58
Issue number	9
DOIs	https://doi.org/10.1111/1365-2664.13941
Publication status	Published - Sep 2021

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 15 Life on Land

Keywords

allometric relationships
biomass and body size measurements
Corbicula
Dreissena
freshwater invasive bivalves
Limnoperna
Sinanodonta
weight conversion equations

Access to Document

10.1111/1365-2664.13941

Cite this

Coughlan, N. E., Cunningham, E. M., Cuthbert, R. N., Joyce, P. W. S., Anastácio, P., Banha, F., Bonel, N., Bradbeer, S. J., Briski, E., Butitta, V. L., Čadková, Z., Dick, J. T. A., Douda, K., Eagling, L. E., Ferreira-Rodríguez, N., Hünicken, L. A., Johansson, M. L., Kregting, L., Labecka, A. M., ... Sylvester, F. (2021). Biometric conversion factors as a unifying platform for comparative assessment of invasive freshwater bivalves. Journal of Applied Ecology, 58(9), 1945-1956. https://doi.org/10.1111/1365-2664.13941

@article{5482946f409a4ceab480347244a73ea5,

title = "Biometric conversion factors as a unifying platform for comparative assessment of invasive freshwater bivalves",

abstract = "Invasive bivalves continue to spread and negatively impact freshwater ecosystems worldwide. As different metrics for body size and biomass are frequently used within the literature to standardise bivalve-related ecological impacts (e.g. respiration and filtration rates), the lack of broadly applicable conversion equations currently hinders reliable comparison across bivalve populations. To facilitate improved comparative assessment among studies originating from disparate geographical locations, we report body size and biomass conversion equations for six invasive freshwater bivalves (or species complex members) worldwide: Corbicula fluminea, C. largillierti, Dreissena bugensis, D. polymorpha, Limnoperna fortunei and Sinanodonta woodiana, and tested the reliability (i.e. precision and accuracy) of these equations. Body size (length, width and height) and biomass metrics of living-weight (LW), wet-weight (WW), dry-weight (DW), dry shell-weight (SW), shell free dry-weight (SFDW) and ash-free dry-weight (AFDW) were collected from a total of 44 bivalve populations located in Asia, the Americas and Europe. Relationships between body size and individual biomass metrics, as well as proportional weight-to-weight conversion factors, were determined. For most species, although inherent variation existed between sampled populations, body size directional measurements were found to be good predictors of all biomass metrics (e.g. length to LW, WW, SW or DW: R2 = 0.82–0.96), with moderate to high accuracy for mean absolute error (MAE): ±9.14\%–24.19\%. Similarly, narrow 95\% confidence limits and low MAE were observed for most proportional biomass relationships, indicating high reliability for the calculated conversion factors (e.g. LW to AFDW; CI range: 0.7–2.0, MAE: ±0.7\%–2.0\%). Synthesis and applications. Our derived biomass prediction equations can be used to rapidly estimate the biologically active biomass of the assessed species, based on simpler biomass or body size measurements for a wide range of situations globally. This allows for the calculation of approximate average indicators that, when combined with density data, can be used to estimate biomass per geographical unit-area and contribute to quantification of population-level effects. These general equations will support meta-analyses, and allow for comparative assessment of historic and contemporary data. Overall, these equations will enable conservation managers to better understand and predict ecological impacts of these bivalves.",

keywords = "allometric relationships, biomass and body size measurements, Corbicula, Dreissena, freshwater invasive bivalves, Limnoperna, Sinanodonta, weight conversion equations",

author = "Coughlan, \{Neil E.\} and Cunningham, \{Eoghan M.\} and Cuthbert, \{Ross N.\} and Joyce, \{Patrick W.S.\} and Pedro Anast{\'a}cio and Filipe Banha and Nicol{\'a}s Bonel and Bradbeer, \{Stephanie J.\} and Elizabeta Briski and Butitta, \{Vince L.\} and Zuzana {\v C}adkov{\'a} and Dick, \{Jaimie T.A.\} and Karel Douda and Eagling, \{Lawrence E.\} and No{\'e} Ferreira-Rodr{\'i}guez and H{\"u}nicken, \{Leandro A.\} and Johansson, \{Mattias L.\} and Louise Kregting and Labecka, \{Anna Maria\} and Deliang Li and Florencia Liquin and Jonathan Marescaux and Morris, \{Todd J.\} and Patrycja Nowakowska and Ma{\l}gorzata O{\.z}go and Paolucci, \{Esteban M.\} and Perib{\'a}{\~n}ez, \{Miguel A.\} and Nicoletta Riccardi and Smith, \{Emily R.C.\} and Spear, \{Michael J.\} and Steffen, \{Gregor T.\} and Tiemann, \{Jeremy S.\} and Maria Urba{\'n}ska and \{Van Doninck\}, Karine and Martin Vastrade and Vong, \{Gina Y.W.\} and Brygida Wawrzyniak-Wydrowska and Zhiqiang Xia and Cong Zeng and Aibin Zhan and Francisco Sylvester",

note = "Publisher Copyright: {\textcopyright} 2021 The Authors. Journal of Applied Ecology published by John Wiley \& Sons Ltd on behalf of British Ecological Society",

year = "2021",

month = sep,

doi = "10.1111/1365-2664.13941",

language = "English",

volume = "58",

pages = "1945--1956",

journal = "Journal of Applied Ecology",

issn = "0021-8901",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "9",

}

Coughlan, NE, Cunningham, EM, Cuthbert, RN, Joyce, PWS, Anastácio, P, Banha, F, Bonel, N, Bradbeer, SJ, Briski, E, Butitta, VL, Čadková, Z, Dick, JTA, Douda, K, Eagling, LE, Ferreira-Rodríguez, N, Hünicken, LA, Johansson, ML, Kregting, L, Labecka, AM, Li, D, Liquin, F, Marescaux, J, Morris, TJ, Nowakowska, P, Ożgo, M, Paolucci, EM, Peribáñez, MA, Riccardi, N, Smith, ERC, Spear, MJ, Steffen, GT, Tiemann, JS, Urbańska, M, Van Doninck, K, Vastrade, M, Vong, GYW, Wawrzyniak-Wydrowska, B, Xia, Z, Zeng, C, Zhan, A & Sylvester, F 2021, 'Biometric conversion factors as a unifying platform for comparative assessment of invasive freshwater bivalves', Journal of Applied Ecology, vol. 58, no. 9, pp. 1945-1956. https://doi.org/10.1111/1365-2664.13941

TY - JOUR

T1 - Biometric conversion factors as a unifying platform for comparative assessment of invasive freshwater bivalves

AU - Coughlan, Neil E.

AU - Cunningham, Eoghan M.

AU - Cuthbert, Ross N.

AU - Joyce, Patrick W.S.

AU - Anastácio, Pedro

AU - Banha, Filipe

AU - Bonel, Nicolás

AU - Bradbeer, Stephanie J.

AU - Briski, Elizabeta

AU - Butitta, Vince L.

AU - Čadková, Zuzana

AU - Dick, Jaimie T.A.

AU - Douda, Karel

AU - Eagling, Lawrence E.

AU - Ferreira-Rodríguez, Noé

AU - Hünicken, Leandro A.

AU - Johansson, Mattias L.

AU - Kregting, Louise

AU - Labecka, Anna Maria

AU - Li, Deliang

AU - Liquin, Florencia

AU - Marescaux, Jonathan

AU - Morris, Todd J.

AU - Nowakowska, Patrycja

AU - Ożgo, Małgorzata

AU - Paolucci, Esteban M.

AU - Peribáñez, Miguel A.

AU - Riccardi, Nicoletta

AU - Smith, Emily R.C.

AU - Spear, Michael J.

AU - Steffen, Gregor T.

AU - Tiemann, Jeremy S.

AU - Urbańska, Maria

AU - Van Doninck, Karine

AU - Vastrade, Martin

AU - Vong, Gina Y.W.

AU - Wawrzyniak-Wydrowska, Brygida

AU - Xia, Zhiqiang

AU - Zeng, Cong

AU - Zhan, Aibin

AU - Sylvester, Francisco

PY - 2021/9

Y1 - 2021/9

N2 - Invasive bivalves continue to spread and negatively impact freshwater ecosystems worldwide. As different metrics for body size and biomass are frequently used within the literature to standardise bivalve-related ecological impacts (e.g. respiration and filtration rates), the lack of broadly applicable conversion equations currently hinders reliable comparison across bivalve populations. To facilitate improved comparative assessment among studies originating from disparate geographical locations, we report body size and biomass conversion equations for six invasive freshwater bivalves (or species complex members) worldwide: Corbicula fluminea, C. largillierti, Dreissena bugensis, D. polymorpha, Limnoperna fortunei and Sinanodonta woodiana, and tested the reliability (i.e. precision and accuracy) of these equations. Body size (length, width and height) and biomass metrics of living-weight (LW), wet-weight (WW), dry-weight (DW), dry shell-weight (SW), shell free dry-weight (SFDW) and ash-free dry-weight (AFDW) were collected from a total of 44 bivalve populations located in Asia, the Americas and Europe. Relationships between body size and individual biomass metrics, as well as proportional weight-to-weight conversion factors, were determined. For most species, although inherent variation existed between sampled populations, body size directional measurements were found to be good predictors of all biomass metrics (e.g. length to LW, WW, SW or DW: R2 = 0.82–0.96), with moderate to high accuracy for mean absolute error (MAE): ±9.14%–24.19%. Similarly, narrow 95% confidence limits and low MAE were observed for most proportional biomass relationships, indicating high reliability for the calculated conversion factors (e.g. LW to AFDW; CI range: 0.7–2.0, MAE: ±0.7%–2.0%). Synthesis and applications. Our derived biomass prediction equations can be used to rapidly estimate the biologically active biomass of the assessed species, based on simpler biomass or body size measurements for a wide range of situations globally. This allows for the calculation of approximate average indicators that, when combined with density data, can be used to estimate biomass per geographical unit-area and contribute to quantification of population-level effects. These general equations will support meta-analyses, and allow for comparative assessment of historic and contemporary data. Overall, these equations will enable conservation managers to better understand and predict ecological impacts of these bivalves.

AB - Invasive bivalves continue to spread and negatively impact freshwater ecosystems worldwide. As different metrics for body size and biomass are frequently used within the literature to standardise bivalve-related ecological impacts (e.g. respiration and filtration rates), the lack of broadly applicable conversion equations currently hinders reliable comparison across bivalve populations. To facilitate improved comparative assessment among studies originating from disparate geographical locations, we report body size and biomass conversion equations for six invasive freshwater bivalves (or species complex members) worldwide: Corbicula fluminea, C. largillierti, Dreissena bugensis, D. polymorpha, Limnoperna fortunei and Sinanodonta woodiana, and tested the reliability (i.e. precision and accuracy) of these equations. Body size (length, width and height) and biomass metrics of living-weight (LW), wet-weight (WW), dry-weight (DW), dry shell-weight (SW), shell free dry-weight (SFDW) and ash-free dry-weight (AFDW) were collected from a total of 44 bivalve populations located in Asia, the Americas and Europe. Relationships between body size and individual biomass metrics, as well as proportional weight-to-weight conversion factors, were determined. For most species, although inherent variation existed between sampled populations, body size directional measurements were found to be good predictors of all biomass metrics (e.g. length to LW, WW, SW or DW: R2 = 0.82–0.96), with moderate to high accuracy for mean absolute error (MAE): ±9.14%–24.19%. Similarly, narrow 95% confidence limits and low MAE were observed for most proportional biomass relationships, indicating high reliability for the calculated conversion factors (e.g. LW to AFDW; CI range: 0.7–2.0, MAE: ±0.7%–2.0%). Synthesis and applications. Our derived biomass prediction equations can be used to rapidly estimate the biologically active biomass of the assessed species, based on simpler biomass or body size measurements for a wide range of situations globally. This allows for the calculation of approximate average indicators that, when combined with density data, can be used to estimate biomass per geographical unit-area and contribute to quantification of population-level effects. These general equations will support meta-analyses, and allow for comparative assessment of historic and contemporary data. Overall, these equations will enable conservation managers to better understand and predict ecological impacts of these bivalves.

KW - allometric relationships

KW - biomass and body size measurements

KW - Corbicula

KW - Dreissena

KW - freshwater invasive bivalves

KW - Limnoperna

KW - Sinanodonta

KW - weight conversion equations

UR - https://www.scopus.com/pages/publications/85109383839

U2 - 10.1111/1365-2664.13941

DO - 10.1111/1365-2664.13941

M3 - Article

AN - SCOPUS:85109383839

SN - 0021-8901

VL - 58

SP - 1945

EP - 1956

JO - Journal of Applied Ecology

JF - Journal of Applied Ecology

IS - 9

ER -

Biometric conversion factors as a unifying platform for comparative assessment of invasive freshwater bivalves

Abstract

UN SDGs

Keywords

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