The present article aims to investigate the contribution of hygroscopic expansion of flax fibres to interfacial radial stresses and Interfacial Shear Strength (IFSS) of Maleic Anhydride grafted Polypropylene (MAPP)/Flax biocomposites. During manufacturing of thermoplastic biocomposites and storage at 50% RH, a weight variation is observed, attributed to water content evolution within plant cell-walls. The hygroscopic radial expansion coefficient beta r (flax) of single flax fibres estimated by Environmental Scanning Electron Microscopy (ESEM) observation is many orders of magnitude higher (beta(f,R) = 1.14 s/Delta m) than thermal expansion (alpha(f,R) = 78 10(-6) epsilon/degrees C). Thus, its contribution to the development of residual stresses sigma(rad) during processing should be prevalent. A multiscale analysis of interfacial stress state and hygroscopic contribution is performed with the use of a cylindrical concentric model at microscopic scale and asymmetric composite laminates [0, 90 degrees] curvature generation at macroscopic scale. Similar radial stresses are obtained, while relevant values of mu (IFSS/sigma(rad)) approximate to 0.46 are calculated. Therefore, the interfacial bond strength of natural fiber/polymer systems should be described by taking into account their hygroscopic behavior. (C) 2017 Elsevier Ltd. All rights reserved.