In minimally invasive surgery (MIS), force feedback is critical for doctors to real-time access surgical tool status and organ information such as tissue structure and hardness, etc.. For instance, the feedback can help doctors to identify a cancerous lump within healthy tissues due to its larger hardness. Recent studies focused on implementing MEMS-typed tactile sensors typically designed with a two-spring element for detecting hardness difference based on a feedback stress or strain ratio in MIS. None of them, however, can truly reflect the real mechanical property of tissues and provide deep sensing capability on organs for real palpation practice. The sensor proposed in the thesis comprises two inkjet printed piezoresistive graphene-based sensing elements back-to-back linked by a freely standing rod for force and displacement detection, respectively. The loaded upper element will result in a deformation directly transferred to press the bottom element into the tissue by the rod. With the same deformation inside the tissues, the bottom element cans, therefore, sense the hardness difference via the feedback force from the tissues. Experimental result shows the sensor can exhibit 2.1 and 5.3mN force feedback from the fat and muscle tissues of pig respectively, while it is pressed with the same 100m displacement to the tissues. ~2.5 times difference in force feedback indicates not only the muscle is harder but also doctors can intuitively percept hardness difference during endosurgery in comparison with the prior arts.