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Abstract Interfacial self‐assembly describes the directed organization of molecules and colloids at phase boundaries. Believed to be fundamental to the inception of primordial life, interfacial assembly is exploited by a myriad of eukaryotic and prokaryotic organisms to execute physiologic activities and maintain homeostasis. Inspired by these natural systems, chemists, engineers, and materials scientists have sought to harness the thermodynamic equilibria at phase boundaries to create multi‐dimensional, highly ordered, and functional nanomaterials. Recent advances in our understanding of the biophysical principles guiding molecular assembly at gas–solid, gas–liquid, solid–liquid, and liquid–liquid interphases have enhanced the rational design of functional bio‐nanomaterials, particularly in the fields of biosensing, bioimaging and biotherapy. Continued development of non‐canonical building blocks, paired with deeper mechanistic insights into interphase self‐assembly, holds promise to yield next generation interfacial bio‐nanomaterials with unique, and perhaps yet unrealized, properties. This article is categorized under:Nanotechnology Approaches to Biology > Nanoscale Systems in BiologyTherapeutic Approaches and Drug Discovery > Emerging Technologies 

Abstract The human colon is home to trillions of microorganisms that modulate gastrointestinal physiology. The understanding of how this gut ecosystem impacts human health, although evolving, is slowed by the lack of accessible tools suitable to studying complex host‐mucus‐microbe interactions. Here, a synthetic gel‐like material capable of recapitulating the varied structural, mechanical, and biochemical profiles of native human colonic mucus is reported to develop compositionally simple microbiome screening platforms with utility in microbiology and drug discovery. The viscous fibrillar material is realized through templated assembly of a fluorine‐rich amino acid at liquid‐liquid interphases. The fluorine‐assisted mucus surrogate (FAMS) can be decorated with mucins to serve as a habitat for microbial colonization and integrated with human colorectal cells to generate artificial mucosae, referred to as a microbiome organoid. Notably, FAMS are made with inexpensive and commercially available materials and can be generated using simple protocols and standard laboratory hardware. As a result, this platform can be broadly incorporated into various laboratory settings to advance probiotic research and inform in vivo approaches. If implemented into high throughput screening approaches, FAMS may represent a valuable tool to study compound metabolism and gut permeability, with an exemplary demonstration of this utility presented here. 

Abstract Deep vein thrombosis (DVT) is a life‐threatening blood clotting condition that, if undetected, can cause deadly pulmonary embolisms. Critical to its clinical management is the ability to rapidly detect, monitor, and treat thrombosis. However, current diagnostic imaging modalities lack the resolution required to precisely localize vessel occlusions and enable clot monitoring in real time. Here, we rationally design fibrinogen‐mimicking fluoropeptide nanoemulsions, or nanopeptisomes (NPeps), that allow contrast‐enhanced ultrasound imaging of thrombi and synchronous inhibition of clot growth. The theranostic duality of NPeps is imparted via their intrinsic binding to integrins overexpressed on platelets activated during coagulation. The platelet‐bound nanoemulsions can be vaporized and oscillate in an applied acoustic field to enable contrast‐enhanced Doppler ultrasound detection of thrombi. Concurrently, nanoemulsions bound to platelets competitively inhibit secondary platelet–fibrinogen binding to disrupt further clot growth. Continued development of this synchronous theranostic platform may open new opportunities for image‐guided, non‐invasive, interventions for DVT and other vascular diseases. 

Abstract Although rarely used in nature, fluorine has emerged as an important elemental ingredient in the design of proteins with altered folding, stability, oligomerization propensities, and bioactivity. Adding to the molecular modification toolbox, here we report the ability of privileged perfluorinated amphiphiles to noncovalently decorate proteins to alter their conformational plasticity and potentiate their dispersion into fluorous phases. Employing a complementary suite of biophysical, in‐silico and in‐vitro approaches, we establish structure‐activity relationships defining these phenomena and investigate their impact on protein structural dynamics and intracellular trafficking. Notably, we show that the lead compound, perfluorononanoic acid, is 10⁶times more potent in inducing non‐native protein secondary structure in select proteins than is the well‐known helix inducer trifluoroethanol, and also significantly enhances the cellular uptake of complexed proteins. These findings could advance the rational design of fluorinated proteins, inform on potential modes of toxicity for perfluoroalkyl substances, and guide the development of fluorine‐modified biologics with desirable functional properties for drug discovery and delivery applications.