Hydrogels are polymeric networks capable of absorbing and retaining large amounts of water. Cryogels are macroporous structures made of monomers or polymeric precursors chemically or physically crosslinked in moderately frozen solutions, and have high water absorption, structural durability, and compressibility. There are few studies on shape memory cryogel, and none is based on cellulose crosslinker. Here we synthesized multifunctional cellulose nanofibers (MCNFs) with aldehyde group as crosslinker to produce chitosan hydrogel and cryogel. The hydrogel (solid content < 2%) had self-healing (~100% healing after injury) and shear thinning properties, verified by rheology. The cryogel showed high water absorption (> 4300%) and good compressibility through dynamic mechanical analyses. The hydrogel and cryogel were both injectable (via 27-gauge and 18-gauge needles, respectively). In particular, the cryogel (nanocellulose:chitosan 1:6) revealed thermally-induced shape memory, of which the mechanism was elucidated by in situ small-angle X-ray scattering (SAXS) and wide-angle X-ray scattering (WAXS). Changes in the orientation of the induced crystalline structure of the cryogel during the shape memory program accounted for its shape memory property. The shape memory allowed the cryogel sheet with a large size (15 mm × 10 mm × 1.1 mm) to be injected through a 16G needle and return to its original shape in 37 °C water. The nanocellulose-chitosan shape memory cryogel showed cytocompatibility and the ability to promote cell growth. The nanocellulose-chitosan hydrogel and cryogel are injectable and degradable biomaterials with adjustable mechanical properties for precision medicine and minimally invasive surgery.