Coastal erosion poses a major threat to low-elevation coastal zones such as Saint-Louis in Senegal, where rapid shoreline retreat has led to community displacement and infrastructure degradation. To address this challenge, nature-based solutions (NbS) have been deployed within the Saint-Louis Marine Protected Area (MPA), notably the installation of “Typhavelles” structures made from Typha australis designed to promote dune formation and reduce erosion. This study assesses the effectiveness of “Typhavelles” using field data collected from 2019 to 2022, complemented by diachronic satellite imagery analysis. Results indicate a notable increase in beach width and dune development across the majority of monitored profiles. Shoreline change analysis reveals a dramatic shift from severe erosion (up to ?94.5 m/year between 2017 and 2019) to significant accretion, reaching up to +136 m/year during the 2019-2021 period following the installation of the “Typhavelles”. These findings demonstrate that “Typhavelles” are effective in trapping sediment and stabilizing the coastline. However, their long-term viability may be compromised by sea level rise, sediment supply limitations, maintenance needs, and material biodegradation. The study highlights the promise of bio-inspired NbS for coastal protection and recommends enhancing “Typhavelles” durability through protective treatments to support broader replication in similar vulnerable coastal zones.
References
[1]
Arkema, K. K., Guannel, G., Verutes, G., Wood, S. A., Guerry, A., Ruckelshaus, M. et al. (2013). Coastal Habitats Shield People and Property from Sea-Level Rise and Storms. Nature Climate Change, 3, 913-918. https://doi.org/10.1038/nclimate1944
[2]
Burcharth, H. F., Hawkins, S. J., Zanuttigh, B., & Lamberti, A. (2007). Environmental Design Guidelines for Low Crested Coastal Structures. Elsevier.
[3]
Diop, E. S., Ndiaye, A., & Sow, B. (2021). Coastal Vulnerability in West Africa: Challenges and Adaptation Strategies. Journal of Coastal Research, 37, 812-826.
[4]
Diouf, A., Cissé, C. O. T., Almar, R., Sy, B., Sy, B. A., Taveneau, A. et al. (2025). Urban Beach Evolution in Saint Louis, Senegal (West Africa) Using Shore-Based Camera Video Monitoring as a Management Tool. Regional Studies in Marine Science, 83, Article ID: 104050. https://doi.org/10.1016/j.rsma.2025.104050
[5]
Fall, M., Kane, A., & Faye, S. (2022). The Role of Bio-Engineering Techniques in Coastal Protection: Evaluating the Impact of Typhavelles in Saint-Louis, Senegal. Sustainable Coastal Management Journal, 5, 105-120.
[6]
FFEM (French Facility for Global Environment) (2022). Soft Solutions to Combat Coastal Erosion in Senegal. https://www.ffem.fr
[7]
Firth, L., Knights, A., Bridger, D., Evans, A., Mieszkowska, N., Moore, P. et al. (2020). Ocean Sprawl: Challenges and Opportunities for Biodiversity Management in a Changing World. Oceanography and Marine Biology—An Annual Review, 58, 193-270. https://doi.org/10.1201/9781315368597-5
[8]
Narayan, S., Beck, M. W., Reguero, B. G., Losada, I. J., van Wesenbeeck, B., Pontee, N. et al. (2016b). The Effectiveness, Costs and Coastal Protection Benefits of Natural and Nature-Based Defences. PLOS ONE, 11, e0154735. https://doi.org/10.1371/journal.pone.0154735
[9]
Narayan, S., Beck, M. W., Wilson, P., Thomas, C. J., Guerrero, A., Shepard, C. C. et al. (2016a). The Value of Coastal Wetlands for Flood Damage Reduction in the Northeastern USA. Scientific Reports, 7, Article No. 9463. https://doi.org/10.1038/s41598-017-09269-z
[10]
Pontee, N., Narayan, S., Beck, M. W., & Hosking, A. H. (2016). Nature-Based Solutions: Lessons from around the World. Proceedings of the Institution of Civil Engineers—Maritime Engineering, 169, 29-36. https://doi.org/10.1680/jmaen.15.00027
[11]
PRCM (Regional Partnership for the Conservation of the Coastal and Marine Zone) (2023). SEDAD Project: An Exchange on Nature-Based Solutions between Senegal, the Gambia, and Mauritania. https://www.prcmarine.org
[12]
Rocle, N., Cormier-Salem, M. C., & Duvail, S. (2020). Community-Led Nature-Based Solutions: An Emerging Approach for Coastal Adaptation in West Africa. Environmental Sustainability Journal, 10, 205-220.
[13]
Sagna, P., Diatta, C., & Gaye, A. T. (2021). Brèche de la Langue de Barbarie et dynamiques côtières à Saint-Louis du Sénégal. Revue Sénégalaise de Géographie, No. 9.
[14]
Schuerch, M., Spencer, T., Temmerman, S., Kirwan, M. L., Wolff, C., Lincke, D. et al. (2018). Future Response of Global Coastal Wetlands to Sea-Level Rise. Nature, 561, 231-234. https://doi.org/10.1038/s41586-018-0476-5
[15]
Seddon, N., Chausson, A., Berry, P., Girardin, C. A. J., Smith, A., & Turner, B. (2020). Understanding the Value and Limits of Nature-Based Solutions to Climate Change and Other Global Challenges. Philosophical Transactions of the Royal Society B: Biological Sciences, 375, Article ID: 20190120. https://doi.org/10.1098/rstb.2019.0120
[16]
Sy, M., Faye, S., & Sambou, H. (2022). Changements côtiers et stratégies d’adaptation à Saint-Louis du Sénégal. Journal Africain des Sciences de l’Environnement, 14, 88-102.
[17]
Sy, O., Sall, M., & Ndiaye, P. (2018). Impacts of Coastal Erosion on the Socio-Economic Stability of Saint-Louis, Senegal. West African Journal of Marine Science, 12, 45-60.
[18]
Thior, M., Sane, T., Sy, O., Descroix, L., Ba, B. D., Solly, B. et al. (2019). Analyse Spatiale de l’évolution du Trait de Côte Autour de l’embouchure du Fleuve Casamance (Sénégal) de 1968 à 2017, à Partir de l’outil DSAS. European Scientific Journal ESJ, 15, 106-130. https://doi.org/10.19044/esj.2019.v15n9p106
[19]
UNEP (United Nations Environment Programme) (2021). Nature-Based Solutions for Coastal Protection: A Policy Guide for West African Nations. https://www.unep.org
[20]
Zanuttigh, B., & van der Meer, J. W. (2008). Design of Low-Crested Structures against Sea Level Rise and Climate Change. Coastal Engineering, 55, 771-784.
