Freshwater Biodiversity Toolbox

Natural Channel Design

Restoring watercourses from human impacts can be accomplished through natural channel design. This intervention involves restoring habitat heterogeneity in lotic systems such as canals, rivers, and streams. The physical and hydrological structure of rivers can be altered through straightening and widening; restoration actions may involve re-meandering rivers, creating heterogeneity by re-establishing riffle and pool sequences. Actions that remove barriers (e.g., weirs, dams) and impervious surfaces such as concrete in these watercourses, coupled with restoring substrate and riparian vegetation, can also improve habitat for many aquatic organisms, especially fish and macroinvertebrates.

Rating:
Four syntheses under this intervention scored poorly in CEESAT. Two syntheses (Feld et al. 2011 & Flávio et al. 2017) scored Green in one element each (defining eligibility criteria and the use of a wide variety of sources). Miller et al. (2010) scored Green across multiple elements of CEESAT, specifically in categories related to the choice of synthesis, statistical estimates, and consideration of limitations in the review and evidence base. Syntheses in this intervention scored well in all but one element of RASCAT. Apart from Miller et al. (2010), all syntheses were unable to demonstrate consideration of implications, practical advice, or recommendations for decision-makers. Photo credit: Toronto and Region Conservation Authority (TRCA)

Miller, S.W., Budy, P., & Schmidt, J.C. (2010)

Quantifying Macroinvertebrate Responses to In-Stream Habitat Restoration: Applications of Meta-Analysis to River Restoration

Title: Quantifying Macroinvertebrate Responses to In-Stream Habitat Restoration: Applications of Meta-Analysis to River Restoration

Authors: Miller, S.W., Budy, P., & Schmidt, J.C.

Journal: Restoration Ecology

Year: 2010

DOI: https://doi.org/10.1111/j.1526-100X.2009.00605.x

Species or groups: Aquatic macroinvertebrates

Other sources of evidence: https://www.conservationevidence.com/actions/1416

Abstract: The assumption that restoring physical habitat heterogeneity will increase biodiversity underlies many river restoration projects, despite few tests of the hypothesis. With over 6,000 in-stream habitat enhancement projects implemented in the last decade at a cost exceeding $1 billion, there is a clear need to assess the consistency of responses, as well as factors explaining project performance. We adopted an alternative approach to individual case-studies by applying meta-analysis to quantify macroinvertebrate responses to in-stream habitat restoration. Meta-analysis of 24 separate studies showed that increasing habitat heterogeneity had significant, positive effects on macroinvertebrate richness, although density increases were negligible. Large woody debris additions produced the largest and most consistent responses, whereas responses to boulder additions and channel reconfigurations were positive, yet highly variable. Among all strategies, the strength and consistency of macroinvertebrate responses were related to land use or watershed-scale conditions, but appeared independent of project size, stream size, or recovery time. Overall, the low quality and quantity of pre- and post-project monitoring data reduced the robustness of our meta-analysis. Specifically, the scope and strength of conclusions regarding the ubiquity of macroinvertebrate responses to restoration, as well as the identification of variables controlling project performance was limited. More robust applications of meta-analysis to advance the science and practice of river restoration will require implementing rigorous study designs, including pre- and post-project monitoring replicated at both restored and control sites, collection of abiotic and biotic variables at relevant spatiotemporal scales, and increased reporting of monitoring results in peer-reviewed journals and/or regional databases.

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Nakano, D., Nagayama, S., Kawaguchi, Y., & Nakamura, F. (2008)

River restoration for macroinvertebrate communities in lowland rivers: Insights from restorations of the Shibetsu River, north Japan

Title: River restoration for macroinvertebrate communities in lowland rivers: Insights from restorations of the Shibetsu River, north Japan

Authors: Nakano, D., Nagayama, S., Kawaguchi, Y., & Nakamura, F.

Journal: Landscape and Ecological Engineering

Year: 2008

DOI: https://doi.org/10.1007/s11355-008-0038-3

Species or groups: Aquatic macroinvertebrates

Other sources of evidence: https://www.conservationevidence.com/actions/1416

Abstract: Because of human impacts, lowland rivers are among the most degraded running water ecosystems, with their floodplains being the center of human activity. Recently, many programs to restore running water ecosystems have been undertaken using various methods in streams and rivers of North America, Europe, and Far East Asia. However, research and knowledge on the effects of river restoration in lowland rivers are limited around the world. The restoration project involving the first reconstruction of a meandering channel in Asia has been conducted in a lowland river section of the Shibetsu River, northern Japan. We review the geomorphologic and hydraulic characteristics of lowland rivers and their environments for macroinvertebrates and discuss approaches to restoring macroinvertebrate communities in lowland rivers, using insights from the restoration project in the Shibetsu River. It is concluded that the recovery of macroinvertebrate assemblages in channelized lowland rivers requires the implementation of restoration methods to create stable substrates.

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Taniguchi, Y., Inoue, M., & Kawaguchi, Y. (2001)

Stream fish habitat science and management in Japan: A review

Title: Stream fish habitat science and management in Japan: A review

Authors: Taniguchi, Y., Inoue, M., & Kawaguchi, Y.

Journal: Aquatic Ecosystem Health and Management

Year: 2001

DOI: https://doi.org/10.1080/146349801317276035

Species or groups: Sakhalin taimen, Masu salmon, Rosyface dace

Other sources of evidence: https://www.conservationevidence.com/actions/1416

Abstract: Japanese freshwater fish habitats can be generally categorized into 1) rivers and streams, 2) ponds and lakes, and 3) rice fields and small irrigation channels connecting them. Of these, reviewing studies on stream fish habitat is the primary objective of this paper. Streams in Japan have widely received severe habitat alterations through construction of artificial instream structures as well as modification of riparian vegetations. As a result, streamdwelling fishes that require natural flow regimes, substrates, and riparian vegetation have declined their populations in great deal in many parts of the country. Recent studies have found riparian forests control water temperature and provide woody debris creating cover structures for the stream fishes resulting in enhancing their carrying capacity. Differences in riparian vegetation types (forest versus grass) played an important role in determining the local distribution of salmonids. Also, experiments removing concrete-lined channel and installing log-drop structures demonstrated that such the treatment greatly improved fish habitat. As the general public became aware of the serious degradation of aquatic habitats, river management policy has gradually shifted to include conservation and improvement of river environment as habitat for wildlife during the last two decades. For fish migration, installation of fishway on dams has been prevailing, and research efforts have been made to design more effective fishway and passable weirs. In many cases, however, such restoration work lacks ecological data for assessment of their effectiveness. When such knowledge on fish habitat are accumulated, a vital issue will be how it is accounted into actual management. Future studies on fish habitat should shift toward treating habitat network at larger spatial scales to seek better designs for distributing appropriate habitats over a whole catchment. Such studies should also include clarifying the habitat requirements of endangered species and effects of non-native on native species.

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Rowiński, P.M., Västilä, K., Aberle, J., Järvelä, J., & Kalinowska, M.B. (2018)

How vegetation can aid in coping with river management challenges: A brief review

Title: How vegetation can aid in coping with river management challenges: A brief review

Authors: Rowiński, P.M., Västilä, K., Aberle, J., Järvelä, J., & Kalinowska, M.B.

Journal: Ecohydrology & Hydrobiology

Year: 2018

DOI: https://doi.org/10.1016/j.ecohyd.2018.07.003

Species or groups: NA

Other sources of evidence: https://www.conservationevidence.com/actions/1416

Abstract: New sustainable, cost-effective solutions are urgently needed for river management since conventional practices have posed serious ecological threats on streams, rivers and the surrounding riparian areas. Besides addressing the societal needs e.g. for flood management, river management should increasingly address the ecosystem requirements for improved water quality and biodiversity. We argue that it is not feasible to solve existing and future river management challenges with intensive restoration projects. Instead, we believe that less resource-intensive solutions using natural channel processes and features, including vegetation, should be investigated. Besides directly supporting biota, aquatic and riparian vegetation traps, takes up and helps to process nutrients and harmful substances, and thus this paper emphasizes vegetation as a tool for nature-based solutions (NBS) in river management. [14TD$DIF]We synthesize findings from key literature, showing that the fate of substances in channel systems is largely controlled by abiotic and biotic processes facilitated and modified by vegetation, including flow hydrodynamics, channel morphology, and sediment transport. Subsequently, we demonstrate how vegetation can be incorporated into channel designs, focusing on a two-stage (compound) design to improve resilience to flooding, control the transport of substances, and enhance the ecological status. As a conclusion, clever use and maintenance of vegetation present [145TD$DIF]an unused potential to obtain large-scale positive environmental impacts in rivers and streams experiencing anthropogenic pressures.

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Flávio, H.M., Ferreira, P., Formigo, N., & Svendsen, J.C. (2017)

Reconciling agriculture and stream restoration in Europe: A review relating to the EU Water Framework Directive

Title: Reconciling agriculture and stream restoration in Europe: A review relating to the EU Water Framework Directive

Authors: Flávio, H.M., Ferreira, P., Formigo, N., & Svendsen, J.C.

Journal: Science of the Total Environment

Year: 2017

DOI: https://doi.org/10.1016/j.scitotenv.2017.04.057

Species or groups: Macroinvertebrates, riparian and aquatic plants, birds, amphibians, fish

Other sources of evidence: https://www.conservationevidence.com/actions/1416

Abstract: Agriculture is widespread across the EU and has caused considerable impacts on freshwater ecosystems. To revert the degradation caused to streams and rivers, research and restoration efforts have been developed to recover ecosystem functions and services, with the European Water Framework Directive (WFD) playing a significant role in strengthening the progress. Analysing recent peer-reviewed European literature (2009–2016), this review explores 1) the conflicts and difficulties faced when restoring agriculturally impacted streams, 2) the aspects relevant to effectively reconcile agricultural land uses and healthy riverine ecosystems and 3) the effects and potential shortcomings of the first WFD management cycle. Our analysis reveals significant progress in restoration efforts, but it also demonstrates an urgent need for a higher number and detail of restoration projects reported in the peer-reviewed literature. The first WFD cycle ended in 2015 without reaching the goal of good ecological status in many European waterbodies. Addressing limitations reported in recent papers, including difficulties in stakeholder integration and importance of small headwater streams, is crucial. Analysing recent developments on stakeholder engagement through structured participatory processes will likely reduce perception discrepancies and increase stakeholder interest during the next WFD planning cycle. Despite an overall dominance of nutrient-related research, studies are spreading across many important topics (e.g. stakeholder management, land use conflicts, climate change effects), which may play an important role in guiding future policy. Our recommendations are important for the second WFD cycle because they 1) help secure the development and dissemination of science-based restoration strategies and 2) provide guidance for future research needs.

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Katopodis, C., & Aadland, L.P. (2006)

Effective dam removal and river channel restoration approaches

Title: Effective dam removal and river channel restoration approaches

Authors: Katopodis, C., & Aadland, L.P.

Journal: International Journal of River Basin Management

Year: 2006

DOI: https://doi.org/10.1080/15715124.2006.9635285

Species or groups: Black bullhead, Freshwater drum, Channel catfish, Walleye, Black crappie, Brassy minnow, Blackside darter, Creek chub, Fathead minnow, Golden redhorse, Johnny Darter, Northern pike, Orange spotted sunfish, Spotfin shiner, Shorthead redhorse, Spottail shiner, Silver redhorse, Stonecast, Tadpole madtom, White bass, White crappie, White sucker, Yellow bullhead, Yellow perch

Other sources of evidence: https://www.conservationevidence.com/actions/1416

Abstract: Millions of dams have been built on the planet’s rivers and streams to provide societal needs for freshwater supplies, irrigation, hydroelectric development, industrial activities and flood control. The structural and operational components of most dams include features that reflect technological advancements and changing societal priorities over time. Many dams were constructed and operated with no consideration for river ecology; some dams have included eco-friendly features (e.g. fish passage facilities, instream flow releases); other dams were modified, replaced or removed. Dams have left their mark on the landscape and the biota that depend on rivers for their entire life cycle or for a part of it. Aquatic organisms (e.g. fish) are particularly sensitive to changes in habitat connectivity, hydrograph alterations, morphodynamic modifications, as well as hydrogeologic, thermal or chemical deviations from natural levels. As various societies around the globe, particularly in recent decades, place a higher priority on river ecosystem health and sustainability, effective approaches to deal with existing and new dams are emerging. Restoration of fluvial processes and ecological functions of rivers may take several forms, including dam replacement or removal. Simple removal of dams can result in sedimentation of downstream habitat, and channel adjustment within the former reservoir may be a long term process before a stable pattern, dimension, and profile becomes established. An alternative approach is to use natural channel design techniques to stabilize accumulated sediment and advance recovery towards a geomorphically stable and ecologically diverse stream. Two approaches and case examples are discussed, one removal with no channel restoration, and one removal with channel restoration. Approaches to dam removal and river restoration involve management, engineering and scientific challenges, demand balanced and sensible resolution, and lead to new research opportunities to fill knowledge gaps of the complex interactions between ecological and physical river processes.

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Feld, C.K., Birk, S., Bradley, D.C., Hering, D., Kail, J., Marzin, A., Melcher, A., Nemitz, D., Pedersen, M.L., Pletterbauer, F., Pont, D., Verdonschot, P.F.M., & Friberg, N. (2011)

From Natural Design to Degraded Rivers and Back Again: A Test of Restoration Ecology Theory and Practices

Title: From Natural Design to Degraded Rivers and Back Again: A Test of Restoration Ecology Theory and Practices

Authors: Feld, C.K., Birk, S., Bradley, D.C., Hering, D., Kail, J., Marzin, A., Melcher, A., Nemitz, D., Pedersen, M.L., Pletterbauer, F., Pont, D., Verdonschot, P.F.M., & Friberg, N.

Journal: NA

Year: 2011

DOI: NA

Species or groups: Benthic macroinvertebrates, Brown trout, Brook trout, Chinook salmon, Grayling, European chub, Gudgeon, periphyton, River limpet

Other sources of evidence: https://www.conservationevidence.com/actions/1416

Abstract: Extensive degradation of ecosystems, combined with the increasing demands placed on the goods and services they provide, is a major driver of biodiversity loss on a global scale. In particular, the severe degradation of large rivers, their catchments, floodplains and lower estuarine reaches has been ongoing for many centuries, and the consequences are evident across Europe. River restoration is a relatively recent tool that has been brought to bear in attempts to reverse the effects of habitat simplification and ecosystem degradation, with a surge of projects undertaken in the 1990s in Europe and elsewhere, mainly North America. Here, we focus on restoration of the physical properties (e.g. substrate composition, bank and bed structure) of river ecosystems to ascertain what has, and what has not, been learned over the last 20 years. First, we focus on three common types of restoration measures- riparian buffer management, instream mesohabitat enhancement and the removal of weirs and small dams- to provide a structured overview of the literature. We distinguish between abiotic effects of restoration (e.g. increasing habitat diversity) and biological recovery (e.g. responses of algae, macrophytes, macroinvertebrates and fishes). We then addressed four major questions: (i) Which organisms show clear recovery after restoration? (ii) Is there evidence for qualitative linkages between restoration and recovery? (iii) What is the timescale of recovery? and (iv) What are the reasons, if restoration fails? Overall, riparian buffer zones reduced fine sediment entry, and nutrient and pesticide inflows, and positive effects on stream organisms were evident. Buffer width and length were key: 5-30 m width and > 1 km length were most effective. The introduction of large woody debris, b,oulders and gravel were the most commonly used restoration measures, but the potential positive effects of such local habitat enhancement schemes were often likely to be swamped by largerscale geomorphological and physico-chemical effects. Studies demonstrating long-term biological recovery due to habitat enhancement were notable by their absence. In contrast, weir removal can have clear beneficial effects, although biological recovery might lag behind for several years, as huge amounts affine sediment may have accumulated upstream of the former barrier. Three Danish restoration schemes are provided as focal case studies to supplement the literature review and largely supported our findings. While the large-scale re-meandering and re-establishment of water levels at River Skjern resulted in significant recovery of riverine biota, habitat enhancement schemes at smaller-scales in other rivers were largely ineffective and failed to show long-term recovery. The general lack of knowledge derived from integrated, well-designed and long-term restoration schemes is striking, and we present a conceptual framework to help address this problem. The framework was applied to the three restoration types included in our study and highlights recurrent causeeffect chains, that is, commonly observed relationships of restoration measures (cause) and their effects on abiotic and biotic conditions (effect). Such conceptual models can provide useful new tools for devising more effective river restoration, and for identifying avenues for future research in restoration ecology in general.

Freshwater Biodiversity Toolbox

Natural Channel Design

Miller, S.W., Budy, P., & Schmidt, J.C. (2010)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Nakano, D., Nagayama, S., Kawaguchi, Y., & Nakamura, F. (2008)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Taniguchi, Y., Inoue, M., & Kawaguchi, Y. (2001)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Rowiński, P.M., Västilä, K., Aberle, J., Järvelä, J., & Kalinowska, M.B. (2018)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Flávio, H.M., Ferreira, P., Formigo, N., & Svendsen, J.C. (2017)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Katopodis, C., & Aadland, L.P. (2006)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Feld, C.K., Birk, S., Bradley, D.C., Hering, D., Kail, J., Marzin, A., Melcher, A., Nemitz, D., Pedersen, M.L., Pletterbauer, F., Pont, D., Verdonschot, P.F.M., & Friberg, N. (2011)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

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Article

Freshwater Biodiversity Toolbox

Natural Channel Design

Miller, S.W., Budy, P., & Schmidt, J.C. (2010)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Nakano, D., Nagayama, S., Kawaguchi, Y., & Nakamura, F. (2008)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Taniguchi, Y., Inoue, M., & Kawaguchi, Y. (2001)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Rowiński, P.M., Västilä, K., Aberle, J., Järvelä, J., & Kalinowska, M.B. (2018)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Flávio, H.M., Ferreira, P., Formigo, N., & Svendsen, J.C. (2017)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Katopodis, C., & Aadland, L.P. (2006)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Feld, C.K., Birk, S., Bradley, D.C., Hering, D., Kail, J., Marzin, A., Melcher, A., Nemitz, D., Pedersen, M.L., Pletterbauer, F., Pont, D., Verdonschot, P.F.M., & Friberg, N. (2011)

Assessment of reliability and robustness (CEESAT)

Assessment of relevance to Canada (RASCAT)

Other Interventions

Find other Interventions

Fencing of Farm Animals

Agricultural Run-off Control

Bycatch Reduction – Fish

Bycatch Reduction – Turtles

Find other Interventions