Hunger and chronic undernourishment impact over 800 million people, which translates to ≈10.7% of the world's population. While countries are increasingly making efforts to reduce poverty and hunger by pursuing sustainable energy and agricultural practices, a third of the food produced around the globe still is wasted and never consumed. Reducing food shortages is vital in this effort and is often addressed by the development of genetically modified produce or chemical additives and inedible coatings, which create additional health and environmental concerns. Herein, a multifunctional bio‐nanocomposite comprised largely of egg‐derived polymers and cellulose nanomaterials as a conformal coating onto fresh produce that slows down food decay by retarding ripening, dehydration, and microbial invasion is reported. The coating is edible, washable, and made from readily available inexpensive or waste materials, which makes it a promising economic alternative to commercially available fruit coatings and a solution to combat food wastage that is rampant in the world.
Proinflammatory cytokines have been approved by the Food and Drug Administration for the treatment of metastatic melanoma and renal carcinoma. However, effective cytokine therapy requires high-dose infusions that can result in antidrug antibodies and/or systemic side effects that limit long-term benefits. To overcome these limitations, we developed a clinically translatable cytokine delivery platform composed of polymer-encapsulated human ARPE-19 (RPE) cells that produce natural cytokines. Tumor-adjacent administration of these capsules demonstrated predictable dose modulation with spatial and temporal control and enabled peritoneal cancer immunotherapy without systemic toxicities. Interleukin-2 (IL2)–producing cytokine factory treatment eradicated peritoneal tumors in ovarian and colorectal mouse models. Furthermore, computational pharmacokinetic modeling predicts clinical translatability to humans. Notably, this platform elicited T cell responses in NHPs, consistent with reported biomarkers of treatment efficacy without toxicity. Combined, our findings demonstrate the safety and efficacy of IL2 cytokine factories in preclinical animal models and provide rationale for future clinical testing in humans.
Despite decades of research, metallic corrosion remains a long‐standing challenge in many engineering applications. Specifically, designing a material that can resist corrosion both in abiotic as well as biotic environments remains elusive. Here a lightweight sulfur–selenium (S–Se) alloy is designed with high stiffness and ductility that can serve as an excellent corrosion‐resistant coating with protection efficiency of ≈99.9% for steel in a wide range of diverse environments. S–Se coated mild steel shows a corrosion rate that is 6–7 orders of magnitude lower than bare metal in abiotic (simulated seawater and sodium sulfate solution) and biotic (sulfate‐reducing bacterial medium) environments. The coating is strongly adhesive, mechanically robust, and demonstrates excellent damage/deformation recovery properties, which provide the added advantage of significantly reducing the probability of a defect being generated and sustained in the coating, thus improving its longevity. The high corrosion resistance of the alloy is attributed in diverse environments to its semicrystalline, nonporous, antimicrobial, and viscoelastic nature with superior mechanical performance, enabling it to successfully block a variety of diffusing species.
BackgroundPro-inflammatory cytokines have been approved by the FDA for the treatment of metastatic melanoma and renal carcinoma.1 2 However, effective cytokine therapy is limited by its short half-life in circulation and the severe adverse effects associated with high systemic exposure. 3 To overcome these limitations, we developed a clinically translatable localized cytokine delivery platform composed of polymer encapsulated epithelial cells that produce localized natural cytokines (IL2, IL7, IL10, or IL12) with temporal regulation.MethodsCytokine PK StudiesSupernatant from individual capsules were assayed at 1-, 2-, 4-, or 24-hours using ELISA (n=6). Mouse Studies: For IP tumor models of ID8-Fluc; 10x106 cells suspended in HBSS were injected in the IP space of female albino C57BL/6 or NU/NU Nude mice (n=4–6). Cytokine factories were implanted 7 days post tumor injection. Primate Studies: Increasing doses of cytokine factories were administered to cynomolgus macaques (n=3). Complete blood count and blood chemistry analysis were performed 28 days after administration. IVIS Imaging: Mice were injected in the IP space with D-luciferin (300 µg/mL, PerkinElmer). Photographs and luminescent images were acquired 10 minutes after injection. Flow Cytometry: All antibodies were commercially obtained and prepared the day of staining. Intracellular staining was performed using the FOXp3/Transcription Factor Staining Buffer Set (Cat. 00-5523-00, eBioscience) and the BD Cytofix/cytoperm fixation/permeabilization solution kit (Cat. 554714, BD Bioscience).ResultsTumor-adjacent local administration of these cytokine factories demonstrated predictable dose modulation with spatial and temporal control and provided ovarian cancer immunotherapy without systemic toxicities. Interestingly, the murine IL2 local concentration (IP space) was greater than 100x higher than the systemic concentration (blood) demonstrating the ability of the platform to deliver native cytokines in vivo and create a high local concentration of cytokines with limited peripheral exposure. A similar concentration differential was seen with IL7, IL10 and IL12. Treatment of peritoneal tumors using IL2 producing cytokine factories provided sustained eradication of peritoneal tumors in an ovarian cancer mouse model. Our data confirmed local increases in the activation (CD25+CD8+) and proliferation (Ki67+CD8+) of cytotoxic T cells within the IP space of cytokine factory treated mice. Significantly, this platform produced local and systemic T cell biomarker profiles that predict efficacy without toxicity in non-human primates.ConclusionsOur findings demonstrate the safety and efficacy of IL2 cytokine factories in preclinical animal models and provide rationale for future clinical testing for the treatment of metastatic peritoneal cancers in humans.ReferencesChoudhry H, Helmi N, Abdulaal WH, Zeyadi M, Zamzami MA, Wu W, Mahmoud MM, Warsi MK, Rasool M, Jamal MS. Prospects of IL-2 in cancer immunotherapy. Biomed Res Int 2018;(2018): 9056173.McDermott DF, Atkins MB. Interleukin-2 therapy of metastatic renal cell carcinoma--predictors of response. Semin Oncol 33(2006):583–587.Muhlradt PF, Opitz HG. Clearance of interleukin 2 from the blood of normal and T cell-depleted mice. Eur J Immunol 12(1982):983–985.Ethics ApprovalAll mouse experiments were approved by Rice University’s Institution Animal Care and Use Committee (IACUC). All cynomolgus macaque procedures and post-operative care were performed in accordance with the Guidelines for Care and Use of Laboratory Animals of the University of Illinois-Chicago (UIC) and approved by the Institutional Use and Animal Care Committee (IACUC) of UIC.
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