Dendritic cells (DCs) play a pivotal role in bridging the innate and adaptive immune systems. From their immature state, scavenging tissue for foreign antigens to uptake, then maturation, to their trafficking to lymph nodes for antigen presentation, these cells are exposed to various forms of mechanical forces. Particularly, in the tumor microenvironment, it is widely known that microenvironmental biomechanical cues are heightened. The source of these forces arises from cell-to-extracellular matrix (ECM) and cell-to-cell interactions, as well as being exposed to increased microenvironmental pressures and fluid shear forces typical of tumors. DCs then integrate these forces, influencing their immune functions through mechanotransduction. This aspect of DC biology holds alternative, but important clues to understanding suppressed/altered DC responses in tumors, or allow the artificial enhancement of DCs for therapeutic purposes. This review discusses the current understanding of DC mechanobiology from the perspectives of DCs as sensors of mechanical forces and providers of mechanical forces.

Cellular behaviors such as migration, spreading, and differentiation arise from the interplay of cell-matrix interactions. The comprehension of this interplay has been advanced by the motor-clutch model, a theoretical framework that captures the binding-unbinding kinetics of mechanosensitive membrane-bound proteins involved in mechanochemical signaling, such as integrins. Since its introduction and subsequent development as a computational tool, the motor clutch model has been instrumental in elucidating the impact of biophysical factors on cellular mechanobiology. This review aims to provide a comprehensive overview of recent advances in the motor-clutch modeling framework, its role in elucidating the relationships between mechanical forces and cellular processes, and its potential applications in mechanomedicine.

Micropatterning is a sophisticated technique that precisely manipulates the spatial distribution of cell adhesion proteins on various substrates across multiple scales. This precise control over adhesive regions facilitates the manipulation of architectures and physical constraints for single or multiple cells. Furthermore, it allows for an in-depth analysis of how chemical and physical properties influence cellular functionality. In this comprehensive review, we explore the current understanding of the impact of geometrical confinement on cellular functions across various dimensions, emphasizing the benefits of micropatterning in addressing fundamental biological queries. We advocate that utilizing directed self-organization via physical confinement and morphogen gradients on micropatterned surfaces represents an innovative approach to generating functional tissue and controlling morphogenesis in vitro. Integrating this technique with cutting-edge technologies, micropatterning presents a significant potential to bridge a crucial knowledge gap in understanding core biological processes.

Dysglycemia causes arterial endothelial damage, which is an early critical event in vascular complications for diabetes patients. Physiologically, moderate shear stress (SS) helps maintain endothelial cell health and normal function. Reactive oxygen species (ROS) and calcium ions (Ca²⁺) signals are involved in dysglycemia-induced endothelial dysfunction and are also implicated in SS-mediated regulation of endothelial cell function. Therefore, it is urgent to establish in vitro models for studying endothelial biomechanics and mechanobiology, aiming to seek interventions that utilize appropriate SS to delay or reverse endothelial dysfunction. Microfluidic technology, as a novel approach, makes it possible to replicate blood glucose environment and accurate pulsatile SS in vitro. Here, we reviewed the progress of microfluidic systems used for SS-mediated repair of dysglycemia-induced endothelial cell damage (ECD), revealing the crucial roles of ROS and Ca²⁺ during the processes. It holds significant implications for finding appropriate mechanical intervention methods, such as exercise training, to prevent and treat cardiovascular complications in diabetes.

A definitive understanding of the interplay between protein binding/migration and membrane curvature evolution is emerging but needs further study. The mechanisms defining such phenomena are critical to intracellular transport and trafficking of proteins. Among trafficking modalities, exosomes have drawn attention in cancer research as these nano-sized naturally occurring vehicles are implicated in intercellular communication in the tumor microenvironment, suppressing anti-tumor immunity and preparing the metastatic niche for progression. A significant question in the field is how the release and composition of tumor exosomes are regulated. In this perspective article, we explore how physical factors such as geometry and tissue mechanics regulate cell cortical tension to influence exosome production by co-opting the biophysics as well as the signaling dynamics of intracellular trafficking pathways and how these exosomes contribute to the suppression of anti-tumor immunity and promote metastasis. We describe a multiscale modeling approach whose impact goes beyond the fundamental investigation of specific cellular processes toward actual clinical translation. Exosomal mechanisms are critical to developing and approving liquid biopsy technologies, poised to transform future non-invasive, longitudinal profiling of evolving tumors and resistance to cancer therapies to bring us one step closer to the promise of personalized medicine.

Among the various families of G protein-couple receptors (GPCR), the adhesion family of GPCRs is specialized by its expansive extracellular region, which facilitates the recruitment of various ligands. Previous hypothesis proposed that aGPCRs are activated by mechanical force, wherein a Stachel peptide is liberated from the GPCR autoproteolysis-inducing (GAIN) domain and subsequently binds to the transmembrane domain (7TM) upon activation. In this review, we summarize recent advancements in structural studies of aGPCRs, unveiling a conserved structural change of the Stachel peptide from the GAIN domain-embedded β-strand conformation to the 7TM-loaded α-helical conformation. Notably, using single-molecule studies, we directly observed the unfolding of GAIN domain and the release of Stachel peptide under physiological level of force, precisely supporting the mechanosensing mechanism for aGPCRs. We observed that the current complex structures of aGPCR adhesion domains with their respective ligands share a common pattern with the C-termini of each binding partner extending in opposite directions, suggesting a similar shearing stretch geometry for these aGPCRs to transmit the mechanical force generated in the circulating environment to the GAIN domain for its unfolding. Outstanding questions, including the relative orientations and interactions between 7TM and its preceding GAIN and adhesion domains of different aGPCRs, may require further structural and mechanical studies at the full-length receptor scale or cell-based level. Our analysis extends the current view of aGPCR structural organization and activation and offers valuable insights for the development of mechanosensor based on aGPCRs or discovery of mechanotherapy against aGPCRs.

Mechanical stimuli are known to play critical roles in mediating tissue repair and regeneration. Recently, this knowledge has led to a paradigm shift toward proactive programming of biological functionalities of biomaterials by leveraging mechanics-geometry-biofunction relationships, which are beginning to shape the newly emerging field of mechanobiomaterials. To profile this emerging field, this article aims to elucidate the fundamental principles in modulating biological responses with material-tissue mechanical interactions, illustrate recent findings on the relationships between material properties and biological responses, discuss the importance of mathematical/physical models and numerical simulations in optimizing material properties and geometry, and outline design strategies for mechanobiomaterials and their potential for tissue repair and regeneration. Given that the field of mechanobiomaterials is still in its infancy, this article also discusses open questions and challenges that need to be addressed.

As local regions in the tumor outstrip their oxygen supply, hypoxia can develop, affecting not only the cancer cells, but also other cells in the microenvironment, including cancer associated fibroblasts (CAFs). Hypoxia is also not necessarily stable over time, and can fluctuate or oscillate. Hypoxia Inducible Factor-1 is the master regulator of cellular response to hypoxia, and can also exhibit oscillations in its activity. To understand how stable, and fluctuating hypoxia influence breast CAFs, we measured changes in gene expression in CAFs in normoxia, hypoxia, and oscillatory hypoxia, as well as measured change in their capacity to resist, or assist breast cancer invasion. We show that hypoxia has a profound effect on breast CAFs causing activation of key pathways associated with fibroblast activation, but reduce myofibroblast activation and traction force generation. We also found that oscillatory hypoxia, while expectedly resulted in a “sub-hypoxic” response in gene expression, it resulted in specific activation of pathways associated with actin polymerization and actomyosin maturation. Using traction force microscopy, and a nanopatterned stromal invasion assay, we show that oscillatory hypoxia increases contractile force generation vs stable hypoxia, and increases heterogeneity in force generation response, while also additively enhancing invasibility of CAFs to MDA-MB-231 invasion. Our data show that stable and unstable hypoxia can regulate many mechnobiological characteristics of CAFs, and can contribute to transformation of CAFs to assist cancer dissemination and onset of metastasis.