Biorobots that harness the power generated by living muscle cells have recently gained interest as an alternative to traditional mechanical robots. However, robust and reliable operation of these biorobots still remains a challenge. Toward this end, we developed a self-stabilizing swimming biorobot that can maintain its submersion depth, pitch, and roll without external intervention. The biorobot developed in this study utilized a fin-based propulsion mechanism. It consisted of a base made from two composite PDMS materials and a thin PDMS cantilever seeded with a confluent layer of heart muscle cells. The characterization of the heart muscle cell sheet revealed the gradual increase of the dynamic contraction force and the static cell traction force, which was accompanied by a linear increase in the expression levels of contractile and cytoskeletal proteins. In the design of the biorobot, instead of relying only on the geometry, we used two composite PDMS materials whose densities were modulated by adding either microballoons or nickel powder. The use of two materials with different mass densities enabled precise control of the weight distribution to ensure a positive restoration force on the biorobot tilted at any angle. The developed biorobot exhibited unique propulsion modes depending on the resting angle of its "fin" or the cantilever, and achieved a maximum velocity of 142 μm s(-1). The technique described in this study to stabilize and propel the biorobot can pave the way for novel developments in biorobotics.
Adherent cells produce cellular traction force (CTF) on a substrate to maintain their physical morphologies, sense external environment, and perform essential cellular functions. Precise characterization of the CTF can expand our knowledge of various cellular processes as well as lead to the development of novel mechanical biomarkers. However, current methods that measure CTF require special substrates and fluorescent microscopy, rendering them less suitable in a clinical setting. Here, we demonstrate a rapid and direct approach to measure the combined CTF of a large cell population using thin polydimethylsiloxane (PDMS) cantilevers. Cells attached to the top surface of the PDMS cantilever produce CTF, which causes the cantilever to bend. The side view of the cantilever was imaged with a low-cost camera to extract the CTF. We characterized the CTF of fibroblasts and breast cancer cells. In addition, we were able to directly measure the contractile force of a suspended cell sheet, which is similar to the CTF of the confluent cell layer before detachment. The demonstrated technique can provide rapid and real-time measurement of the CTF of a large cell population and can directly characterize its temporal dynamics. The developed thin film PDMS cantilever can be fabricated affordably and the CTF extraction technique does not require expensive equipment. Thus, we believe that the developed method can provide an easy-to-use and affordable platform for CTF characterization in clinical settings and laboratories.
Biological machines often referred to as biorobots, are living cell- or tissue-based devices that are powered solely by the contractile activity of living components. Due to their inherent advantages, biorobots are gaining interest as alternatives to traditional fully artificial robots. Various studies have focused on harnessing the power of biological actuators, but only recently studies have quantitatively characterized the performance of biorobots and studied their geometry to enhance functionality and efficiency. Here, we demonstrate the development of a self-stabilizing swimming biorobot that can maintain its pitch, depth, and roll without external intervention. The design and fabrication of the PDMS scaffold for the biological actuator and biorobot followed by the functionalization with fibronectin is described in this first part. In the second part of this two-part article, we detail the incorporation of cardiomyocytes and characterize the biological actuator and biorobot function. Both incorporate a base and tail (cantilever) which produce fin-based propulsion. The tail is constructed with soft lithography techniques using PDMS and laser engraving. After incorporating the tail with the device base, it is functionalized with a cell adhesive protein and seeded confluently with cardiomyocytes. The base of the biological actuator consists of a solid PDMS block with a central glass bead (acts as a weight). The base of the biorobot consists of two composite PDMS materials, Ni-PDMS and microballoon-PDMS (MB-PDMS). The nickel powder (in Ni-PDMS) allows magnetic control of the biorobot during cells seeding and stability during locomotion. Microballoons (in MB-PDMS) decrease the density of MB-PDMS, and enable the biorobot to float and swim steadily. The use of these two materials with different mass densities, enabled precise control over the weight distribution to ensure a positive restoration force at any angle of the biorobot. This technique produces a magnetically controlled self-stabilizing swimming biorobot.
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