In this research, Poly(vinyl alcohol)- and Poly(N-isopropylacrylamide) based copolymers and their pharmatical composites were prepared as the medical platform with pH/magnetic/thermo properties for providing the novel and effective diagnosis and treatment toward tumor tissues. Three divided sections were contained in this thesis. In the first section, reversible addition-fragmentation chain transfer (RAFT) polymerization was performed and applied to synthesize ABA tri-block copolymers via living polymerization. In the second section, we fabricated several kinds of multi-functional nanomedicines as the extended employments of the as-synthesized block copolymers. Besides, their biomedical properties of nanomedicines were also obtained with in vitro and in vivo tests. In the third section, double-emulsion method was conducted for core-shell, PVA-based nanoparticles as well as the anti-cancer drugs’ encapsulation. Additionally, acid-cleavable, nanodiscs-based nanoscaffold was designed and prepared via EDC/NHS initiated crosslinking between the synthesized acid-degradable diamines and PEGylated nanodiscs. Platinum and Fe3O4 core-shell nanoparticles were designed and constructed by temperature-induced emulsion of the poly(N-isopropylacrylamide) following with electroless plating methods. The results were both shown in the appendix section. Chapter 2 was contained in the first section and RAFT polymerization with S,S'-bis(a,a'-dimethyl-a"-acetic acid)trithiocarbonate (CMP) as the chain transfer agent (CTA) were demonstrated. By using the thermal initiation following with the RAFT polymerization in methanol, ABA tri-block copolymers, poly(acrylic acid-block-N-isopropylacrylamide-block-acrylic acid), poly(AA-b-NIPAAm-b-AA) with precise control of the main chain composition to the repeating monomer units were prepared. Moreover, further discussions were studied toward the morphology and physical property changes resulting from the different composition ratio of NIPAAm to AA ratio and the system conditions involving pH values and temperatures. Various shapes of poly(AA-b-NIPAAm-b-AA)-based, self-assembly nanoparticles including core-shell nanoparticle, physical crosslinked nanogel, and inversed physically crosslinked nanogel formed at specific conditions. To the best of our knowledge, this was the first research that focus on the relationship between chemical structure and physical properties of poly(AA-b-NIPAAm-b-AA) tri-block copolymers systemically. The second section includes Chapter 3 and Chapter 4, in which different nanocarriers were fabricated and studied for bio-medical applications. In Chapter 3, physically crosslinked nanogels were employed into the preparation of anti-cancer nanomedicine. Magnetic iron oxide (Fe3O4) was introduced to achieve the remote control as well as the stability of magnetic nanocarriers. Furthermore, the intelligent functionality of nanocarriers was realized resulting from highly pH- and magnetically- sensitive quality because of the iron oxides and the functional groups (-COOH and -NH2) on its surface. Chapter 4 contains the following work related of Chapter 3, in which we further modified the magnetic nanocarriers with folic acid to gain the cancer cell-selectivity and replaced the model drug into the hydrophobic one, curcumin. Various release and pharmatical parameters such as biocompatibility, cytotoxicity, cell selectivity, and release behaviors were studied. Chapter 5 was contained in the third section where we paid more attention to develop another way of nanocarriers’ preparation including double-emulsion, sol-gel reaction, and following with targeting ligand immobilization. Both in vitro and in vivo experiments were brought out to give a full scope of pharmatical applications of the magnetic nanocarriers toward tumor therapy. In Appendix 1, we prepared the thermo- and pH-sensitive, fluorescent-labeled nanocarriers with two kinds of drug-loading process. Rhodamine 6G, a fluorescent dye, was used as the modeling drugs not only to demonstrate the release behavior but also for maintaining the spherical structure of self-assembled telechelic HOOC-PNIPAAm-COOH homopolymers. In Appendix 2, PEGylated lipids were mixed with long-chain and short-chain lipids to form carboxylic acids-exposed nanodiscs (a-discs). An acid-degradable diamine was synthesized and applied for stringing the nanodisc in order to enlarge their size for preventing the un-desired cellular uptake and providing controlled release as an anti-cancer platform. Attentions were concentrated on acquiring a stable, well-dispersed Fe3O4 and platinum composite for the purpose of reusable and recyclable catalysis in Appendix 3. Emulsion as well as the electroless plating synthesis with poly(N-isopropylacrylamide) as the matrix were utilized.