Jessica Rhudy

Giving new life to old lungs: methods to produce and assess whole human paediatric bioengineered lungs.

We report, for the first time, the development of an organ culture system and protocols to support recellularization of whole acellular (AC) human paediatric lung scaffolds. The protocol for paediatric lung recellularization was developed using human transformed or immortalized cell lines and single human AC lung scaffolds. Using these surrogate cell populations, we identified cell number requirements, cell type and order of cell installations, flow rates and bioreactor management methods necessary for bioengineering whole lungs. Following the development of appropriate cell installation protocols, paediatric AC scaffolds were recellularized using primary lung alveolar epithelial cells (AECs), vascular cells and tracheal/bronchial cells isolated from discarded human adult lungs. Bioengineered paediatric lungs were shown to contain well‐developed vascular, respiratory epithelial and lung tissue, with evidence of alveolar–capillary junction formation. Types I and II AECs were found thoughout the paediatric lungs. Furthermore, surfactant protein‐C and ‐D and collagen I were produced in the bioengineered lungs, which resulted in normal lung compliance measurements. Although this is a first step in the process of developing tissues for transplantation, this study demonstrates the feasibility of producing bioengineered lungs for clinical use. Copyright

Enhanced gene delivery in porcine vasculature tissue following incorporation of adeno-associated virus nanoparticles into porous silicon microparticles

There is an unmet clinical need to increase lung transplant successes, patient satisfaction and to improve mortality rates. We offer the development of a nanovector-based solution that will reduce the incidence of lung ischemic reperfusion injury (IRI) leading to graft organ failure through the successful ex vivo treatment of the lung prior to transplantation. The innovation is in the integrated application of our novel porous silicon (pSi) microparticles carrying adeno-associated virus (AAV) nanoparticles, and the use of our ex vivo lung perfusion/ventilation system for the modulation of pro-inflammatory cytokines initiated by ischemic pulmonary conditions prior to organ transplant that often lead to complications. Gene delivery of anti-inflammatory agents to combat the inflammatory cascade may be a promising approach to prevent IRI following lung transplantation. The rationale for the device is that the microparticle will deliver a large payload of virus to cells and serve to protect the AAV from immune recognition. The microparticle-nanoparticle hybrid device was tested both in vitro on cell monolayers and ex vivo using either porcine venous tissue or a pig lung transplantation model, which recapitulates pulmonary IRI that occurs clinically post-transplantation. Remarkably, loading AAV vectors into pSi microparticles increases gene delivery to otherwise non-permissive endothelial cells.

Adjuvant Cationic Liposomes Presenting MPL and IL-12 Induce Cell Death, Suppress Tumor Growth, and Alter the Cellular Phenotype of Tumors in a Murine Model of Breast Cancer

Dendritic cells (DC) process and present antigens to T lymphocytes, inducing potent immune responses when encountered in association with activating signals, such as pathogen-associated molecular patterns. Using the 4T1 murine model of breast cancer, cationic liposomes containing monophosphoryl lipid A (MPL) and interleukin (IL)-12 were administered by intratumoral injection. Combination multivalent presentation of the Toll-like receptor-4 ligand MPL and cytotoxic 1,2-dioleoyl-3-trmethylammonium-propane lipids induced cell death, decreased cellular proliferation, and increased serum levels of IL-1β and tumor necrosis factor (TNF)-α. The addition of recombinant IL-12 further suppressed tumor growth and increased expression of IL-1β, TNF-α, and interferon-γ. IL-12 also increased the percentage of cytolytic T cells, DC, and F4/80+ macrophages in the tumor. While single agent therapy elevated levels of nitric oxide synthase 3-fold above basal levels in the tumor, combination therapy with MPL cationic liposomes and IL-12 stimulated a 7-fold increase, supporting the observed cell cycle arrest (loss of Ki-67 expression) and apoptosis (TUNEL positive). In mice bearing dual tumors, the growth of distal, untreated tumors mirrored that of liposome-treated tumors, supporting the presence of a systemic immune response.

Multivalent Presentation of MPL by Porous Silicon Microparticles Favors T Helper 1 Polarization Enhancing the Anti-Tumor Efficacy of Doxorubicin Nanoliposomes

Porous silicon (pSi) microparticles, in diverse sizes and shapes, can be functionalized to present pathogen-associated molecular patterns that activate dendritic cells. Intraperitoneal injection of MPL-adsorbed pSi microparticles, in contrast to free MPL, resulted in the induction of local inflammation, reflected in the recruitment of neutrophils, eosinophils and proinflammatory monocytes, and the depletion of resident macrophages and mast cells at the injection site. Injection of microparticle-bound MPL resulted in enhanced secretion of the T helper 1 associated cytokines IFN-γ and TNF-α by peritoneal exudate and lymph node cells in response to secondary stimuli while decreasing the anti-inflammatory cytokine IL-10. MPL-pSi microparticles independently exhibited anti-tumor effects and enhanced tumor suppression by low dose doxorubicin nanoliposomes. Intravascular injection of the MPL-bound microparticles increased serum IL-1β levels, which was blocked by the IL-1 receptor antagonist Anakinra. The microparticles also potentiated tumor infiltration by dendritic cells, cytotoxic T lymphocytes, and F4/80+ macrophages, however, a specific reduction was observed in CD204+ macrophages.

Porcine acellular lung matrix for wound healing and abdominal wall reconstruction: A pilot study

Surgical wound healing applications require bioprosthetics that promote cellular infiltration and vessel formation, metrics associated with increased mechanical strength and resistance to infection. Porcine acellular lung matrix is a novel tissue scaffold known to promote cell adherence while minimizing inflammatory reactions. In this study, we evaluate the capacity of porcine acellular lung matrix to sustain cellularization and neovascularization in a rat model of subcutaneous implantation and chronic hernia repair. We hypothesize that, compared to human acellular dermal matrix, porcine acellular lung matrix would promote greater cell infiltration and vessel formation. Following pneumonectomy, porcine lungs were processed and characterized histologically and by scanning electron microscopy to demonstrate efficacy of the decellularization. Using a rat model of subcutaneou implantation, porcine acellular lung matrices (n = 8) and human acellular dermal matrices (n = 8) were incubated in vivo for 6 weeks. To evaluate performance under mechanically stressed conditions, porcine acellular lung matrices (n = 7) and human acellular dermal matrices (n = 7) were implanted in a rat model of chronic ventral incisional hernia repair for 6 weeks. After 6 weeks, tissues were evaluated using hematoxylin and eosin and Masson’s trichrome staining to quantify cell infiltration and vessel formation. Porcine acellular lung matrices were shown to be successfully decellularized. Following subcutaneous implantation, macroscopic vessel formation was evident. Porcine acellular lung matrices demonstrated sufficient incorporation and showed no evidence of mechanical failure after ventral hernia repair. Porcine acellular lung matrices demonstrated significantly greater cellular density and vessel formation when compared to human acellular dermal matrix. Vessel sizes were similar across all groups. Cell infiltration and vessel formation are well-characterized metrics of incorporation associated with improved surgical outcomes. Porcine acellular lung matrices are a novel class of acellular tissue scaffold. The increased cell and vessel density may promote long-term improved incorporation and mechanical properties. These findings may be due to the native lung scaffold architecture guiding cell migration and vessel formation. Porcine acellular lung matrices represent a new alternative for surgical wound healing applications where increased cell density and vessel formation are sought.

Production and transplantation of bioengineered lung into a large-animal model

Nanoparticle delivery of growth factors promotes capillary development in bioengineered lungs during bioreactor culture and transplantation in a pig model. New life for lungs Lungs are complex organs to engineer: They contain multiple specialized cell types in extracellular matrix with a unique architecture that must maintain compliance during respiration. Nichols et al. tackled the challenges of vascular perfusion, recellularization, and engraftment of tissue-engineered lungs in a clinically relevant pig model. Nanoparticle and hydrogel delivery of growth factors promoted cell adhesion to whole decellularized pig lung scaffolds. Autologous cell–seeded bioengineered lungs showed vascular perfusion via collateral circulation within 2 weeks after transplantation. The transplanted bioengineered lungs became aerated and developed native lung-like microbiomes. One pig had no respiratory symptoms when euthanized a full 2 months after transplant. This work represents a considerable advance in the lung tissue engineering field and brings tissue-engineered lungs closer to the realm of clinical possibility. The inability to produce perfusable microvasculature networks capable of supporting tissue survival and of withstanding physiological pressures without leakage is a fundamental problem facing the field of tissue engineering. Microvasculature is critically important for production of bioengineered lung (BEL), which requires systemic circulation to support tissue survival and coordination of circulatory and respiratory systems to ensure proper gas exchange. To advance our understanding of vascularization after bioengineered organ transplantation, we produced and transplanted BEL without creation of a pulmonary artery anastomosis in a porcine model. A single pneumonectomy, performed 1 month before BEL implantation, provided the source of autologous cells used to bioengineer the organ on an acellular lung scaffold. During 30 days of bioreactor culture, we facilitated systemic vessel development using growth factor–loaded microparticles. We evaluated recipient survival, autograft (BEL) vascular and parenchymal tissue development, graft rejection, and microbiome reestablishment in autografted animals 10 hours, 2 weeks, 1 month, and 2 months after transplant. BEL became well vascularized as early as 2 weeks after transplant, and formation of alveolar tissue was observed in all animals (n = 4). There was no indication of transplant rejection. BEL continued to develop after transplant and did not require addition of exogenous growth factors to drive cell proliferation or lung and vascular tissue development. The sterile BEL was seeded and colonized by the bacterial community of the native lung.

Nanofluidic drug-eluting seed for sustained intratumoral immunotherapy in triple negative breast cancer

ABSTRACT Conventional systemic immunotherapy administration often results in insufficient anti‐tumor immune response and adverse side effects. Delivering immunotherapeutics intratumorally could maximize tumor exposure, elicit efficient anti‐tumor immune response, and minimize toxicity. To fulfill the unmet clinical need for sustained local drug delivery and to avoid repeated intratumoral injections, we developed a nanofluidic‐based device for intratumoral drug delivery called the nanofluidic drug‐eluting seed (NDES). The NDES is inserted intratumorally using a minimally invasive trocar method similar to brachytherapy seed insertion and offers a clinical advantage of drug elution. Drug diffusion from the NDES is regulated by physical and electrostatic nanoconfinement, thereby resulting in constant and sustained immunotherapeutic delivery without the need for injections or clinician intervention. In this study, the NDES was used to deliver immunotherapeutics intratumorally in the 4T1 orthotopic murine mammary carcinoma model, which recapitulates triple negative breast cancer. We demonstrated that NDES‐mediated intratumoral release of agonist monoclonal antibodies, OX40 and CD40, resulted in potentiation of local and systemic anti‐tumor immune response and inhibition of tumor growth compared to control mice. Further, mice treated with NDES‐CD40 demonstrated minimal liver damage compared to systemically treated mice. Collectively, our study highlights the NDES as an effective platform for sustained intratumoral immunotherapeutic delivery. The potential clinical impact is tremendous given that the NDES is applicable to a broad spectrum of drugs and solid tumors.

Abstract 2594: Adjuvant cationic nanoliposomes induce anti-cancer immunity in a murine model of breast cancer

Proceedings: AACR Annual Meeting 2014; April 5-9, 2014; San Diego, CA Nanoparticles, such as liposomes, provide opportunities to simultaneously present antigens and immune modulators. Using a 4T1 murine model of breast cancer, a cationic nanoliposomal formulation containing monophosphoryl lipid A and the cationic lipid 1,2-dioleoyl-3-trimethylammonium-propane induced anti-tumor activity following intratumoral administration. Addition of recombinant interleukin-12 (IL-12) further suppressed tumor growth and augmented T helper-1 cell (Th-1) polarization, with enhanced tumor infiltration by cytotoxic T cells, dendritic cells, and M1 macrophages, and amplification of interferon gamma secretion. Mice bearing dual tumors displayed arrest of tumor growth in treated tumors as well as distal, untreated tumors following combination therapy with adjuvant nanoliposomes and IL-12. In summary, adjuvant MPL-liposomes combined with localized IL-12 therapy block tumor growth, stimulate a Th-1 bias of the tumor microenvironment, and induce cancer-specific immune responses. Citation Format: Ismail M. Meraz, David J. Savage, Jianhua Gu, Jessica Rhudy, Rita E. Serda. Adjuvant cationic nanoliposomes induce anti-cancer immunity in a murine model of breast cancer. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 2594. doi:10.1158/1538-7445.AM2014-2594