Three-dimensional tumor models, methods of manufacturing same and uses thereof

What is claimed is: 1 . A three dimensional (3D) model of a tumor comprising a synthetic material, which is not inherently present in the tumor or its environment or in a subject having the tumor and a plurality of cell types having a full HLA match, said plurality of cell types comprising malignant cells and non-malignant cells of said tumor, wherein the 3D model features a plurality of voxel blocks, wherein at least 70% of said voxel blocks are identical to corresponding voxel blocks of a 3D imaging data of said tumor or part thereof, cells of which having been used to generate said 3D model. 2 . The 3D model of claim 1 , comprising extracellular matrix. 3 . The 3D model of claim 1 , comprising a perfusable vasculature. 4 . The 3D model of claim 1 , further comprising components of an extracellular matrix (ECM) of said tumor. 5 . The 3D model of claim 1 , wherein said synthetic material is selected from the group consisting of gelatin methacrylate (GelMA), Fmoc-containing material, Acrylated hyaluronic acid, poly-(ethylene glycol) diacrylate (PEGDA), clay mineral and carbon nanotubes chitosan, alginate, xanthan gum and pectin. 6 . A method of manufacturing a 3D model of a tumor of a subject, the method comprising: (a) imaging said tumor to acquire a 3D imaging data of said tumor; and subsequently (b) ex-vivo dissociating at least a portion of said tumor so as to obtain a cell suspension comprising a plurality of cell types; and subsequently (c) subjecting said cell suspension to bioprinting according to said 3D imaging data so as to obtain a 3D model of said tumor, wherein said 3D model features a plurality of voxel blocks, wherein at least 70% of said voxel blocks are identical to corresponding voxel blocks of said 3D imaging data. 7 . The method of claim 6 , wherein said cell suspension comprises a plurality of cell suspensions fractionating said plurality of cell types, such that each of said cell suspensions comprises a different composition of said plurality of cell types. 8 . The method of claim 6 , wherein said cell suspension comprises an extracellular matrix. 9 . The method of claim 6 , further comprising perfusing said 3D-bioprinted model of said tumor, to thereby obtain a perfused model. 10 . The method of claim 6 , further comprising: (d) isolating cells of said tumor model; (e) in vitro or in vivo culturing said cells. 11 . The method of claim 6 further comprising ex-vivo dissociating a surrounding environment of said tumor. 12 . The method of claim 6 , further comprising imaging a surrounding environment of said tumor prior to said ex-vivo dissociating. 13 . A system comprising the 3D model of claim 1 and a container in fluid communication with the 3D model, said container comprising immune cells and/or a therapeutically active agent. 14 . A method of screening for an anti-cancer treatment regimen, the method comprising: subjecting a 3D model of a tumor according to claim 1 to said anti-cancer treatment regimen; and determining a presence of an anti-cancer effect of said anti-cancer treatment regimen at a personalized manner. 15 . A method of screening for an anti-cancer treatment regimen, the method comprising: subjecting a system of claim 13 to said anti-cancer treatment regimen; and determining a presence of an anti-cancer effect of said anti-cancer treatment regimen at a personalized manner. 16 . A method of characterizing a tumor, the method comprising: providing the 3D model of the tumor of claim 1 ; isolating cells of said model; in vitro or in vivo culturing said cells.