More Like this

1. Blood-brain-barrier modeling with tissue chips for research applications in space and on Earth

   https://doi.org/10.3389/frspt.2023.1176943  

   Yau, Anne ; Jogdand, Aditi ; Chen, Yupeng ( August 2023 , Frontiers in Space Technologies)

   Tissue chip technology has revolutionized biomedical applications and the medical science field for the past few decades. Currently, tissue chips are one of the most powerful research tools aiding in in vitro work to accurately predict the outcome of studies when compared to monolayer two-dimensional (2D) cell cultures. While 2D cell cultures held prominence for a long time, their lack of biomimicry has resulted in a transition to 3D cell cultures, including tissue chips technology, to overcome the discrepancies often seen in in vitro studies. Due to their wide range of applications, different organ systems have been studied over the years, one of which is the blood brain barrier (BBB) which is discussed in this review. The BBB is an incredible protective unit of the body, keeping out pathogens from entering the brain through vasculature. However, there are some microbes and certain diseases that disrupt the function of this barrier which can lead to detrimental outcomes. Over the past few years, various designs of the BBB have been proposed and modeled to study drug delivery and disease modeling on Earth. More recently, researchers have started to utilize tissue chips in space to study the effects of microgravity on human health. BBB tissue chips in space can be a tool to understand function mechanisms and therapeutics. This review addresses the limitations of monolayer cell culture which could be overcome with utilizing tissue chips technology. Current BBB models on Earth and how they are fabricated as well as what influences the BBB cell culture in tissue chips are discussed. Then, this article reviews how application of these technologies together with incorporating biosensors in space would be beneficial to help in predicting a more accurate physiological response in specific tissue or organ chips. Finally, the current platforms used in space and some solutions to overcome some shortcomings for future BBB tissue chip research are also discussed. 

   more » « less
2. Altered Biodistribution and Tissue Retention of Nanoparticles Targeted with Pglycoprotein Substrates

   Crawford, Lindsey ; Watkins, Hannah ; Wayne, Elizabeth ; Putnam, David ( January 2019 , Cornell University Library)

   Low molecular weight substrates of the efflux transporter, P-glycoprotein, alter the biodistribution and tissue retention of nanoparticles following intravenous administration. Of particular interest is the retention of the targeted nanoparticles in the brain. Drug delivery to the brain is hindered by the restricted transport of drugs through the blood-brain barrier (BBB). Drugs that passively diffuse across the BBB also have large volumes of distribution; therefore, alteration of their biodistribution to increase their concentration in the brain may help to enhance efficacy and reduce off-target side effects. In this work, targeted nanoparticles were used to explore a new approach to target drugs to the brain--the exploitation of the P-glycoprotein efflux pump. The retention of nanoparticles containing a strong P-glycoprotein substrate, rhodamine 6G, tethered to a PLA nanoparticle through a PEG spacer was greater than two-fold relative to untargeted nanoparticles and to nanoparticles tethered to a weaker Pglycoprotein substrate, rhodamine 123. In a P-glycoprotein knockout mouse model (mdr1a (-/-)), there were no significant differences in brain accumulation between rhodamine 6G targeted particles and controls, strongly supporting the role of Pglycoprotein. This proof of concept report shows the potential applicability of low molecular weight P-gp substrates to alter nanoparticle biodistribution. 

   more » « less
3. COVID‐19 as a Blood Clotting Disorder Masquerading as a Respiratory Illness: A Cerebrovascular Perspective and Therapeutic Implications for Stroke Thrombectomy

   https://doi.org/10.1111/jon.12770  

   Janardhan, Vallabh ; Janardhan, Vikram ; Kalousek, Vladimir ( August 2020 , Journal of Neuroimaging)

   Severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) as the name suggests was initially thought to only cause a respiratory illness. However, several reports have been published of patients with ischemic strokes in the setting of coronavirus disease 2019 (COVID‐19). The mechanisms of how SARS‐CoV‐2 results in blood clots and large vessel strokes need to be defined as it has therapeutic implications. SARS‐CoV‐2 enters the blood stream by breaching the blood‐air barrier via the lung capillary adjacent to the alveolus, and then attaches to the angiotensin‐converting enzyme II receptors on the endothelial cells. Once SARS‐CoV‐2 enters the blood stream, a cascade of events (Steps 1‐8) unfolds including accumulation of angiotensin II, reactive oxygen species, endothelial dysfunction, oxidation of beta 2 glycoprotein 1, formation of antiphospholipid antibody complexes promoting platelet aggregation, coagulation cascade, and formation of cross‐linked fibrin blood clots, leading to pulmonary emboli (PE) and large vessel strokes seen on angiographic imaging studies. There is emerging evidence for COVID‐19 being a blood clotting disorder and SARS‐CoV‐2 using the respiratory route to enter the blood stream. As the blood‐air barrier is breached, varying degrees of collateral damage occur. Although antiviral and immune therapies are studied, the role of blood thinners in the prevention, and management of blood clots in Covid‐19 need evaluation. In addition to ventilators and blood thinners, continuous aspiration and clot retrieval devices (approved in Europe, cleared in the United States) or cyclical aspiration devices (approved in Europe) need to be considered for the emergent management of life‐threatening clots including PE and large vessel strokes.

    

   more » « less
4. Connecting gut microbiomes and short chain fatty acids with the serotonergic system and behavior in Gallus gallus and other avian species

   https://doi.org/10.3389/fphys.2022.1035538  

   Jadhav, Vidya V. ; Han, Jian ; Fasina, Yewande ; Harrison, Scott H. ( November 2022 , Frontiers in Physiology)

   Monika Proszkowiec-Weglarz, Agricultural Research (Ed.)

   The chicken gastrointestinal tract has a diverse microbial community. There is increasing evidence for how this gut microbiome affects specific molecular pathways and the overall physiology, nervous system and behavior of the chicken host organism due to a growing number of studies investigating conditions such as host diet, antibiotics, probiotics, and germ-free and germ-reduced models. Systems-level investigations have revealed a network of microbiome-related interactions between the gut and state of health and behavior in chickens and other animals. While some microbial symbionts are crucial for maintaining stability and normal host physiology, there can also be dysbiosis, disruptions to nutrient flow, and other outcomes of dysregulation and disease. Likewise, alteration of the gut microbiome is found for chickens exhibiting differences in feather pecking (FP) behavior and this alteration is suspected to be responsible for behavioral change. In chickens and other organisms, serotonin is a chief neuromodulator that links gut microbes to the host brain as microbes modulate the serotonin secreted by the host’s own intestinal enterochromaffin cells which can stimulate the central nervous system via the vagus nerve. A substantial part of the serotonergic network is conserved across birds and mammals. Broader investigations of multiple species and subsequent cross-comparisons may help to explore general functionality of this ancient system and its increasingly apparent central role in the gut-brain axis of vertebrates. Dysfunctional behavioral phenotypes from the serotonergic system moreover occur in both birds and mammals with, for example, FP in chickens and depression in humans. Recent studies of the intestine as a major site of serotonin synthesis have been identifying routes by which gut microbial metabolites regulate the chicken serotonergic system. This review in particular highlights the influence of gut microbial metabolite short chain fatty acids (SCFAs) on the serotonergic system. The role of SCFAs in physiological and brain disorders may be considerable because of their ability to cross intestinal as well as the blood-brain barriers, leading to influences on the serotonergic system via binding to receptors and epigenetic modulations. Examinations of these mechanisms may translate into a more general understanding of serotonergic system development within chickens and other avians.

    

   more » « less
5. A Soluble Platelet-Derived Growth Factor Receptor-β Originates via Pre-mRNA Splicing in the Healthy Brain and Is Upregulated during Hypoxia and Aging

   https://doi.org/10.3390/biom13040711  

   Payne, Laura Beth ; Abdelazim, Hanaa ; Hoque, Maruf ; Barnes, Audra ; Mironovova, Zuzana ; Willi, Caroline E. ; Darden, Jordan ; Houk, Clifton ; Sedovy, Meghan W. ; Johnstone, Scott R. ; et al ( April 2023 , Biomolecules)

   The platelet-derived growth factor-BB (PDGF-BB) pathway provides critical regulation of cerebrovascular pericytes, orchestrating their investment and retention within the brain microcirculation. Dysregulated PDGF Receptor-beta (PDGFRβ) signaling can lead to pericyte defects that compromise blood-brain barrier (BBB) integrity and cerebral perfusion, impairing neuronal activity and viability, which fuels cognitive and memory deficits. Receptor tyrosine kinases such as PDGF-BB and vascular endothelial growth factor-A (VEGF-A) are often modulated by soluble isoforms of cognate receptors that establish signaling activity within a physiological range. Soluble PDGFRβ (sPDGFRβ) isoforms have been reported to form by enzymatic cleavage from cerebrovascular mural cells, and pericytes in particular, largely under pathological conditions. However, pre-mRNA alternative splicing has not been widely explored as a possible mechanism for generating sPDGFRβ variants, and specifically during tissue homeostasis. Here, we found sPDGFRβ protein in the murine brain and other tissues under normal, physiological conditions. Utilizing brain samples for follow-on analysis, we identified mRNA sequences corresponding to sPDGFRβ isoforms, which facilitated construction of predicted protein structures and related amino acid sequences. Human cell lines yielded comparable sequences and protein model predictions. Retention of ligand binding capacity was confirmed for sPDGFRβ by co-immunoprecipitation. Visualizing fluorescently labeled sPDGFRβ transcripts revealed a spatial distribution corresponding to murine brain pericytes alongside cerebrovascular endothelium. Soluble PDGFRβ protein was detected throughout the brain parenchyma in distinct regions, such as along the lateral ventricles, with signals also found more broadly adjacent to cerebral microvessels consistent with pericyte labeling. To better understand how sPDGFRβ variants might be regulated, we found elevated transcript and protein levels in the murine brain with age, and acute hypoxia increased sPDGFRβ variant transcripts in a cell-based model of intact vessels. Our findings indicate that soluble isoforms of PDGFRβ likely arise from pre-mRNA alternative splicing, in addition to enzymatic cleavage mechanisms, and these variants exist under normal physiological conditions. Follow-on studies will be needed to establish potential roles for sPDGFRβ in regulating PDGF-BB signaling to maintain pericyte quiescence, BBB integrity, and cerebral perfusion—critical processes underlying neuronal health and function, and in turn, memory and cognition. 

   more » « less