生物工程

Plastic pollution presents a looming danger to the environment and virtually all life on planet Earth. Especially pernicious are nanoplastics (NPs), which are plastic fragments with dimensions ≤1 μm. Conventional detection methods are ineffective for NPs, while their high specific surface area renders them efficient carriers of toxic substances; additionally, they may even be inherently toxic. Although NP waste chiefly arises from environmental weathering of larger plastic fragments, most published studies employed manufactured pristine NPs of uniform size and shape. Furthermore, almost all NP effects were studied using polystyrene (PS) as a convenient model material, despite PS accounting for <6% of all plastic pollution. There is thus an urgent need to expand investigations of environmental NP pollution and effects on biota. The present work provides a comprehensive roadmap for studying the effects of “real-world” NP pollution on living systems, using, for example, lung alveolar epithelial cells on which such NPs deposit by breathing ambient air. Herein, we describe detailed in-house methods to fabricate various NPs that are weathered with UV light and O₃ gas exposure to more closely mimic real environmental NPs. We also illustrate a simple and straightforward bioelectrical method for assessing passive and active ion transport properties of primary rat lung alveolar epithelial cell monolayers as a model for the distal mammalian lung exposed to one of the generated NPs. This protocol allows researchers to rapidly and more accurately assess the biological impact of various simulated environmental NPs on a vulnerable air–blood barrier in the lung.

Continuous and balanced bone remodeling is essential for maintaining mechanical integrity, mineral homeostasis, and hematopoiesis. Dysregulated bone metabolism develops pathological conditions, such as osteoporosis and bone metastasis. Functional and analytical recapitulation of bone remodeling in vitro is critical for advancing our understanding of bone mineral metabolism, disease mechanisms, and drug development. However, conventional models fail to replicate the essential complexity of the bone extracellular matrix (ECM) and the dynamic interplay between bone-forming osteoblasts and bone-resorbing osteoclasts. Recently, we developed an osteoid-mimicking demineralized bone paper (DBP) by thin-sectioning demineralized bovine compact bone matrix. DBP supports osteoblastic mineral deposition and the subsequent transition to bone-lining cells. When co-cultured with bone marrow mononuclear cells under biochemical stimulation, osteoblasts shift their regulatory secretion profiles and effectively induce osteoclastogenesis. The semi-transparent nature of DBP, combined with primary osteogenic cells retrieved from DsRed and eGFP reporter mice, enables longitudinal fluorescent monitoring of these multicellular processes and quantitative analysis. In this protocol, we describe the methods for DBP generation, reconstituting mineralized bone tissue complexity with osteoblasts, and recapitulating the bone remodeling cycle through bone marrow monocytes co-culture under biochemical stimulation, offering a useful platform for the related and broader research community.

Fluorescent protein biosensors (FPBs) that turn on—go from dark to bright upon binding their ligands—enable the detection of targets in living cells with high sensitivity and spatial localization. Several approaches exist for creating turn-on FPBs, most notably the method that gave rise to the GCaMP family of genetically encoded calcium indicators. However, it remains challenging to modify these sensors to recognize new ligands. We recently developed adaptable turn-on maturation (ATOM) biosensors, in which target recognition by a small binding domain triggers chromophore maturation in the fluorescent protein to which it is attached. ATOM sensors are advantageous because they are generalizable (by virtue of the monobody and nanobody binding domains) and modular (binding domains and fluorescent proteins of various colors can be mixed and matched for multiplexed imaging), capable of detecting endogenously expressed proteins, and able to function in subcellular compartments including the cytoplasm, nucleus, endoplasmic reticulum, and mitochondria. The protocols herein detail how to design, clone, and screen new ATOM sensors for detecting targets of choice. The starting materials are the genes encoding for a monobody or nanobody and for a cyan, yellow, or red fluorescent protein. We also present general guidelines for creating ATOM sensors using binding domains other than nanobodies and monobodies.

Dual-modal imaging, combining photoacoustic (PA) and ultrasound localization (UL) with microbubbles, holds substantial promise across biomedical fields such as oncology, neuroscience, nephrology, and immunology. The combination of PA and UL imaging faces challenges due to acquisition speed mismatches, limiting their combined efficacy. Here, we introduce a protocol that applies sparsity constraint optimization to accelerate dual-modal data acquisition, enabling in vivo super-resolution imaging of vascular and physiological structures at under two seconds per frame. The protocol provides detailed guidelines for constructing an interleaved PA/UL (PAUL) imaging system, covering material selection, system setup, and calibration, as well as methods for image acquisition, reconstruction, post-processing, and troubleshooting. This approach empowers the biomedical community to establish a rapid, dual-modal PAUL imaging platform, broadening biomedical applications and advancing imaging capabilities in clinical research.

Interstitial fluid (ISF) is a promising diagnostic sample due to its extensive biomolecular content while being safer and less invasive to collect than blood. However, existing ISF sampling methods are time-consuming, require specialized equipment, and yield small amounts of fluid (<5 μL). We have recently reported a simple and minimally invasive technique for rapidly sampling larger quantities of dermal ISF using a microneedle (MN) array to generate micropores in the skin from which ISF is extracted using a vacuum-assisted skin patch. Here, we present step-by-step protocols for fabricating the MN array and skin patch, as well as for using them to sample ISF from human skin. Using this technique, an average of 20.8 μL of dermal ISF can be collected within 25 min, which is a ∼6-fold improvement over existing ISF sampling methods. Furthermore, the technique is well-tolerated and does not require the use of expensive or specialized equipment. The ability to collect ample volumes of ISF in a quick and minimally invasive manner will facilitate the analysis of ISF for biomarker discovery and its use for diagnostic testing.

Chloroplast genomes present an alternative strategy for large-scale engineering of photosynthetic eukaryotes. Prior to our work, the chloroplast genomes of Chlamydomonas reinhardtii (204 kb) and Zea mays (140 kb) had been cloned using bacterial and yeast artificial chromosome (BAC/YAC) libraries, respectively. These methods lack design flexibility as they are reliant upon the random capture of genomic fragments during BAC/YAC library creation; additionally, both demonstrated a low efficiency (≤ 10%) for correct assembly of the genome in yeast. With this in mind, we sought to create a highly flexible and efficient approach for assembling the 117 kb chloroplast genome of Phaeodactylum tricornutum, a photosynthetic marine diatom. Our original article demonstrated a PCR-based approach for cloning the P. tricornutum chloroplast genome that had 90%–100% efficiency when screening as few as 10 yeast colonies following assembly. In this article, we will discuss this approach in greater depth as we believe this technique could be extrapolated to other species, particularly those with a similar chloroplast genome size and architecture.

Droplet microfluidic platforms have been broadly used to facilitate DNA transfer in mammalian and bacterial hosts via methods such as transformation, transfection, and conjugation, as introduced in our previous work. Herein, we recapitulate our method for conjugal DNA transfer between Bacillus subtilis strains in a droplet for increased conjugation efficiency and throughput of an otherwise laborious protocol. By co-incubating the donor and recipient strains in droplets, our method confines cells into close proximity allowing for increased cell-to-cell interactions. This methodology is advantageous in its potential to automate and accelerate the genetic modification of undomesticated organisms that may be difficult to cultivate. This device is also designed for modularity and can be integrated into a variety of experimental workflows in which fine-tuning of donor-to-recipient cell ratios, growth rates, and media substrate concentrations may be necessary.

This study explores the novel application of pyronin Y for fluorescently labeling extracellular matrices (ECMs) and gelatin cryogels, providing a simple and reliable method for laser scanning confocal microscopy. Pyronin Y exhibited remarkable staining ability of the porous structures of gelatin cryogels, indicating its potential as a reliable tool for evaluating such biomaterials. Confocal imaging of pyronin Y–stained cryogels produced high signal-to-noise ratio images suitable for quantifying pores using Fiji/Image J. Importantly, pyronin Y enabled effective dual-color imaging of cryogel-labeled mesenchymal stem cells, expanding its utility beyond traditional RNA assays. Traditional staining methods like Mason’s trichrome and Sirius Red have limitations in cryogel applications. Pyronin Y emerges as a powerful alternative due to its water solubility, minimal toxicity, and stability. Our results demonstrate pyronin Y’s ability to specifically stain gelatin cryogel's porous structures, surpassing its weak staining of ECMs in 2D. Confocal imaging revealed enduring staining even under rigorous scanning, with no notable photobleaching observed. Furthermore, pyronin Y's combination with Alexa Fluor 647 for dual-color imaging showed promising results, validating its versatility in fluorescence microscopy. In conclusion, this study establishes pyronin Y as a cost-effective and rapid option for fluorescent staining of gelatin cryogels. Its simplicity, efficacy, and compatibility with confocal microscopy make it a valuable tool for characterizing and evaluating gelatin-based biomaterials, contributing significantly to the field of cryogel imaging. The study opens new avenues for dual-color imaging in biomaterial research and tissue engineering, advancing our understanding of cellular interactions within scaffolds.

Adipose tissue is crucial for medical applications such as tissue reconstruction, cosmetic procedures, and correcting soft tissue deformities. Significant advances in the use of adipose tissue have been achieved through Coleman’s studies in fat grafting, which gained widespread acceptance due to its effectiveness and safety. Despite its benefits, adipose tissue grafting faces several limitations, including high absorption rates due to insufficient support or anchorage, replacement by fibrous tissue, migration from the intended site, and loss of the initial desired morphology post-administration. To counteract these constraints, there is a need for improved grafting techniques that enhance the predictability and consistency of outcomes. Biomaterials are extensively used in tissue engineering to support cell adhesion, proliferation, and growth. Both natural and synthetic materials have shown promise in creating suitable microenvironments for adipose tissue regeneration. PLGA, a synthetic copolymer, is particularly notable for its biocompatibility, biodegradability, and tunable mechanical properties. Here, we describe a protocol using milled electrospun poly(lactic-co-glycolic acid) (PLGA) fibers combined with lipoaspirated tissue to create a fibrous slurry for injection. By pulverizing PLGA fiber mats to create fiber fragments with increased pore size and porosity, we can influence key cellular responses and enhance the success of adipose tissue–grafting procedures. This approach improves anchorage and support for adipocytes, thereby increasing cell viability. This method aims to enhance vascularity, perfusion, and volume retention in adipose tissue grafts, which addresses many of the limitations of current approaches to adipose tissue grafting and holds promise for more consistent and successful outcomes.

Endometrial cancer (EC) is the leading cause of gynecologic cancer morbidity and mortality in the U.S. Despite advancements in cancer research, EC death rates are increasing, particularly high-grade endometrial cancers. The development of three-dimensional (3D) patient-derived organoid (PDO) models for EC is crucial, as they provide a more accurate representation of the biological and genetic complexity of a patient’s tumor compared to traditional 2D cell lines. Here, we describe a protocol for cultivating PDO models from normal endometrium and EC across different EC subtypes. These EC PDO models can be expanded across multiple passages and facilitate the exploration of tumor behavior and drug responses, thereby advancing our understanding of the disease and potentially leading to more effective and individualized novel therapeutic strategies.