Metformin Treatment of Macrophages Increases Microvessel Growth in Three-Dimensional Hydrogel Coculture.

The global population is aging rapidly, posing unprecedented challenges to health care systems. This study investigates the often-overlooked role of macrophages in microvascular dysfunction associated with aging. We use a three-dimensional hydrogel model to assess the effects of both age and metformin, an anti-aging therapeutic, on macrophage interactions with microvasculature.

A Biomaterial Model to Assess the Effects of Age in Vascularization.

As humans age, there is an increased risk for developing age-associated diseases. Many of these diseases, such as cardiovascular disease, involve dysfunction in the vasculature. Cardiovascular disease stems from endothelial cell dysfunction and reduction in vascularization.

Ancestral Background Is Underreported in Regenerative Engineering.

Purpose: The ancestral background of human cells may play a role in cells' behavior and response to therapeutic interventions in vitro. We investigate the prevalence of ancestry reporting in current biological research and suggest that increased reporting would be beneficial to the field.

Methods: Articles published over a six-month period in ten different journals were reviewed for their use of human primary cells and immortalized cell lines, and were analyzed based on whether or not the ancestral or ethnic information of cell donors was ascertainable.

Modeled vascular microenvironments: immune-endothelial cell interactions in vitro.

The advancement of in vitro techniques enables a better understanding of biological processes and improves drug screening platforms. In vitro studies allow for enhanced observation of cell behavior, control over the mimicked microenvironment, and the ability to use human cells. In particular, advances in vascular microenvironment recapitulation are of interest given vasculature influence in cardiovascular vascular diseases and cancer.

Macrophages in microgravity: the impact of space on immune cells.

The effects of a microgravity environment on the myriad types of immune cells present within the human body have been assessed both by bench-scale simulation and suborbital methods, as well as in true spaceflight. Macrophages have garnered increased research interest in this context in recent years. Their functionality in both immune response and tissue remodeling makes them a unique cell to investigate in regards to gravisensitive effects as well as parameters of interest that could impact astronaut health.