Modeling mucus physiology and pathophysiology in human organs-on-chips.

The surfaces of human internal organs are lined by a mucus layer that ensures symbiotic relationships with commensal microbiome while protecting against potentially injurious environmental chemicals, toxins, and pathogens, and disruption of this layer can contribute to disease development. Studying mucus biology has been challenging due to the lack of physiologically relevant human in vitro models. Here we review recent progress that has been made in the development of human organ-on-a-chip microfluidic culture models that reconstitute epithelial tissue barriers and physiologically relevant mucus layers with a focus on lung, colon, small intestine, cervix and vagina.

Plugging the Leaky Pipeline: The Role of Peer Mentorship for Increasing Diversity.

I arrived to my shift early, nervous about caring for critically ill patients as a first-year fellow. I sat in the workroom alone, paralyzed, not sure how to preround despite being months into fellowship. The senior fellow appeared minutes before sign-out; fresh, knowledgeable, and calm, despite her busy night and lack of sleep.

Nutritional deficiency in an intestine-on-a-chip recapitulates injury hallmarks associated with environmental enteric dysfunction.

Environmental enteric dysfunction (EED)-a chronic inflammatory condition of the intestine-is characterized by villus blunting, compromised intestinal barrier function and reduced nutrient absorption. Here we show that essential genotypic and phenotypic features of EED-associated intestinal injury can be reconstituted in a human intestine-on-a-chip lined by organoid-derived intestinal epithelial cells from patients with EED and cultured in nutrient-deficient medium lacking niacinamide and tryptophan. Exposure of the organ chip to such nutritional deficiencies resulted in congruent changes in six of the top ten upregulated genes that were comparable to changes seen in samples from patients with EED.

Enteric Coronavirus Infection and Treatment Modeled With an Immunocompetent Human Intestine-On-A-Chip.

Many patients infected with coronaviruses, such as SARS-CoV-2 and NL63 that use ACE2 receptors to infect cells, exhibit gastrointestinal symptoms and viral proteins are found in the human gastrointestinal tract, yet little is known about the inflammatory and pathological effects of coronavirus infection on the human intestine. Here, we used a human intestine-on-a-chip (Intestine Chip) microfluidic culture device lined by patient organoid-derived intestinal epithelium interfaced with human vascular endothelium to study host cellular and inflammatory responses to infection with NL63 coronavirus. These organoid-derived intestinal epithelial cells dramatically increased their ACE2 protein levels when cultured under flow in the presence of peristalsis-like mechanical deformations in the Intestine Chips compared to when cultured statically as organoids or in Transwell inserts.

Establishment of a Modular Anaerobic Human Intestine Chip.

It is impossible to analyze human-specific host-microbiome interactions using animal models and existing in vitro methods fail to support survival of human cells in direct contact with complex living microbiota for extended times. Here we describe a protocol for culturing human organ-on-a-chip (Organ Chip) microfluidic devices lined by human patient-derived primary intestinal epithelium in the presence of a physiologically relevant transluminal hypoxia gradient that enables their coculture with hundreds of different living aerobic and anaerobic bacteria found within the human gut microbiome. This protocol can be adapted to provide different levels of oxygen tension to facilitate coculturing of microbiome from different regions of gastrointestinal tract, and the same system can be applied with any other type of Organ Chip.

Human Colon-on-a-Chip Enables Continuous In Vitro Analysis of Colon Mucus Layer Accumulation and Physiology.

Background & Aims: The mucus layer in the human colon protects against commensal bacteria and pathogens, and defects in its unique bilayered structure contribute to intestinal disorders, such as ulcerative colitis. However, our understanding of colon physiology is limited by the lack of in vitro models that replicate human colonic mucus layer structure and function. Here, we investigated if combining organ-on-a-chip and organoid technologies can be leveraged to develop a human-relevant in vitro model of colon mucus physiology.

Author Correction: A complex human gut microbiome cultured in an anaerobic intestine-on-a-chip.

In the version of this Article originally published, the authors mistakenly cited Fig. 5d in the sentence beginning 'Importantly, the microbiome cultured in these primary Intestine Chips..

A complex human gut microbiome cultured in an anaerobic intestine-on-a-chip.

The diverse bacterial populations that comprise the commensal microbiome of the human intestine play a central role in health and disease. A method that sustains complex microbial communities in direct contact with living human intestinal cells and their overlying mucus layer in vitro would thus enable the investigation of host-microbiome interactions. Here, we show the extended coculture of living human intestinal epithelium with stable communities of aerobic and anaerobic human gut microbiota, using a microfluidic intestine-on-a-chip that permits the control and real-time assessment of physiologically relevant oxygen gradients.

Maternal Attitudes and Other Factors Associated with Infant Vaccination Status in the United States, 2011-2014.

Objective: To assess the role of maternal attitudes and other factors associated with infant vaccination status.

Study Design: Data on reported vaccination status were analyzed from a nationally representative prospective survey of mothers of 2- to 6-month-old infants. Weighted univariate and multiple logistic regression analyses were conducted.