| 1. |
- Shafaat, Atefeh
(författare)
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Development of Wireless Biosensors Integrated into the Radio Frequency Antenna for Chipless and Battery-less Monitoring of Biological Reactions
- 2023
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Development of wireless sensors and biosensors is currently experiencing a rapid progress with a substantial focus directed toward highlighting their potential applications as non-invasive wearables, implants, and highly mobile point-of-care devices. Integration of wireless biosensors into the Internet of Things (IoT) is widely acknowledged as a technological advancement with the potential to significantly change daily life. To maximize this potential, simple integration of biosensors with wireless communication elements would be advantageous. In this regard, systems functioning in chipless, and battery-less modes outperform integrated circuit (IC) based and battery-powered wireless biosensors. Nevertheless, the accessibility of these wireless designs is still limited. In this study, we present a novel approach where incorporating silver nanoparticles(AgNPs) as a part of the radio frequency (RF) tag antenna enables the realization of simple, chipless, and battery-less wireless sensing of biological oxidation and reduction reactions. We exemplified the mechanism of operation in such systems by electronic wiring of enzymes through direct electron transfer (DET) and microorganisms through mediated electron transfer (MET) to the redox conversion of Ag/AgCl. The wiring was designed to facilitate the transformation of metallic AgNPs into AgCl (Ag → AgCl) or the conversion of AgCl particles back into metallic AgNPs (AgCl → Ag) when the enzymatic/microorganism based electron transfer reactions were present. These reactions occurring on the biosensor RF tag antenna strongly changed the impedance of the tag, which was wirelessly monitored by a radio frequency identification (RFID) reader. The functionality of the proposed setup in direct electron transfer coupling of the enzymatic reactions to the redox conversion of the Ag/AgCl was demonstrated by wireless detection of glucose in whole blood samples and hydrogen peroxide penetrated through the skin membrane using the enzymes glucose dehydrogenase(GDH) and horseradish peroxidase (HRP). Additionally, the capability of the proposed configuration in mediated electron transfer wiring of microorganisms to the Ag/AgCl electrochemistry was shown by wireless monitoring of medically relevant microbial biofilms in simulated wound fluid. Generalizing, the results of this work, for the first time, demonstrated that exploiting Ag/AgCl as a part of the tag antenna allows simple, chipless, and battery-less wireless sensing of biological oxidation and reduction reactions.
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| 2. |
- Utterström, Johanna, 1993-
(författare)
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Design and Optimization of Membrane Active Peptides and Lipid Vesicles for Triggered Release
- 2024
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Liposomes can reduce toxic side effects and improve the efficacy of drugs and several liposome-based drug formulations are approved for clinical use. The therapeutic effect is dependent on the bioavailability of the drug and a slow drug release from liposomes can reduce their efficacy. Multiple strategies have been proposed to control the release of drugs from liposomes using both external stimuli such as light, heat and ultrasound, and endogenous factors such as changes in pH or enzymatic activity. However, because of the difficulties to efficiently modulate lipid membrane permeability and the challenges to trigger drug release in the target tissue, no stimuli responsive liposomes have so far been approved. There is consequently a great need for new means to tune lipid membrane integrity for liposome cargo release to improve the development of new advanced drug delivery systems for better and safer treatment of patients. The aim of this thesis was to design and explore synthetic membrane active peptides for triggered release from liposomes and to expand the knowledge on how peptide-lipid conjugation strategies and lipid properties affect the membrane activity of the peptides. This work was based on two different de novo designed cationic and amphipathic, conjugation-dependent membrane active peptides (CKV4 and JR2KC). Both peptides fold and adopt α-helical structures upon conjugation to liposomes, triggering lipid membrane destabilization. Addition of cholesterol in the lipid membrane greatly enhanced the release efficiency of JR2KC due to a peptide-triggered lipid phase separation, resulting in domains with high local peptide concentrations. Additionally, both peptide surface concentrations and lipid net charge were found to be important factors for efficient release. However, when the zeta potential decreased below -75 mV, conjugation-independent release mechanisms were triggered. Liposome size was shown to only have minor effects on the release kinetics for both sets of peptides while a mixture of saturated and unsaturated lipids was beneficial for the peptide-triggered membrane destabilization, possibly due to increased propensity for lipid phase separation. In addition to changing lipid properties, peptide-lipid conjugation strategies proved to highly affect the release kinetics, where the Michael addition reaction between a cysteine in the peptide and maleimide-lipids was much more efficient in causing peptide-triggered membrane destabilization than strain-promoted alkyne azide cycloaddition reactions using azide-modified peptides and DBCO-functionalized lipids. However, thiols tend to oxidize under ambient conditions which complicates peptide-lipid conjugation. This was addressed by synthesizing a peptide with a cysteine modified with an enzyme labile thiol protection group. Enzymatic deprotection allowed efficient peptide-lipid conjugation, reducing the risk of peptide oxidation. To further find means to tailor peptide-lipid interactions, we explored the effect of a competing peptide heterodimerization process on lipid membrane destabilization. Addition of a charge complementary peptide to CKV4 resulted in heterodimerization and folding into a coiled coil, which inhibited its membrane activity. However, when the two peptides were synthesized as a single sequence, the membrane activity was altered, most likely due to the induced preorganization increasing membrane affinity. The results presented in this thesis provide new understandings of the complex peptide-lipid interactions that govern peptide-induced release from liposomes and will facilitate further optimization in peptide design for the future development of advanced liposome-based drug delivery systems.
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| 3. |
- Blasi Romero, Anna
(författare)
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Bioactive nanocellulose materials for the treatment of chronic wounds
- 2023
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Chronic wounds represent a burden for the healthcare system and significantly affect the quality of life of the patients. There is currently a lack of efficient treatments but new, improved therapeutic approaches are under development. Suggested innovative wound care therapies consist on the topical administration of bioactive compounds aimed at restoring the balance in the wound environment and promoting the healing. However, their effectiveness is limited due to the highly oxidative and proteolytic environment in the chronic wound. In the work presented in this thesis, a series of bioactive nanocellulose-based materials were developed with the aim of addressing some of the present demands in chronic wound care. Wood-derived cellulose nanofibrils (CNFs) were functionalized with selected bioactive molecules expected to endow CNFs with the ability to modulate the chronic wound environment. Different chemical approaches were explored to combine CNFs with the following biomolecules: the amino acid cysteine, the peptide oligoproline and the host defense peptide KR-12. Materials were characterized in terms of chemical structure, degree of substitution and bioactivity.The immobilization of cysteine onto CNFs (cys-CNF) provided the material with radical oxygen species (ROS) scavenging properties and the ability to inhibit protease activity, properties that were related to the presence of free thiol groups on the nanofibers. Storage conditions in an inert atmosphere or in the form of aerogel were proposed to assure the long-term activity of the cys-CNF material. Investigations on the use of the ROS-sensitive oligoproline to crosslink CNFs provided optimized protocols to maximize peptide substitution and the degree of crosslinking. The oligoproline-CNF materials were sensitive to ROS-mediated cleavage and provided a protective effect to cells exposed to oxidative conditions. Moreover, the feasibility of preparing ROS-responsive drug delivery hydrogels based on the oligoproline-CNF was demonstrated, with indications that tuning the length of the oligoproline peptide could be exploited to tailor the release rate of small proteins. CNF materials with antibacterial properties and the ability to modulate the response of pro-inflammatory macrophages were obtained by immobilizing KR-12 derivatives onto CNFs. This study highlighted the importance in the selection of the conjugation chemistry to preserve the activity of the peptide once immobilized. To conclude, this work has contributed with valuable strategies to develop bioactive CNF-based materials with the potential of paving the way for advanced solutions in the field of chronic wound care.
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| 4. |
- Jury, Michael, 1984-
(författare)
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Modular Hyaluronan-Based Hydrogels for 3D Cell Culture and Bioprinting
- 2022
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Three-dimensional (3D) cell culture facilitates development of biological relevant assays for drug screening and toxicity testing. Compared to conventional 2D cell culture, cells cultured in 3D can more accurately mimic human tissues and organs and thus provide ex vivo data with potentially better predictive value for cancer research, pharmacology, and toxicology, reducing the need for animal models, improving experimental reproducibility, and reducing time and costs in drug development. The most widely used options for scaffold-based 3D cell culture are, however, based on poorly defined biologically derived extracellular matrix (ECM) with limited possibilities to tailor material properties and that are difficult to combine with state-of-the art biofabrication techniques. The overall aim this thesis was to design and explore modular hyaluronan (HA) based ECM-mimicking hydrogels with tuneable physiochemical properties and biofunctionalities, for development of advanced 3D cell models and biofabrication. The thesis work is presented in five papers. In paper I, we used copper free click chemistry for both hydrogel cross-linking and functionalization with fibronectin derived peptide sequences for culture of human induced pluripotent-derived hepatocytes in a perfused microfluidic system. The tuneable and bioorthogonal cross-linking enabled both retention of high cell viabilities and fabrication of a functional liver-on-chip solution. In paper II, we combined the developed HA-based hydrogel system with homo- and heterodimerizing helix-loop-helix peptides for modulation of both cross-linking density and biofunctionalization. We further demonstrated the possibilities to use these hydrogels as bioinks for 3D bioprinting where both the molecular composition and the physical properties of the printed structures could be dynamically altered, providing new avenues for four-dimensional (4D) bioprinting. In paper III we investigated the possibilities to chemically conjugate full size recombinant human laminin-521 (LN521) in the HA-based hydrogels system using copper-free click chemistry, with the aim to enable 3D culture and 3D bioprinting of neurons. We quantified the impact of using different linkers to tether LN521 and the influence of LN-functionalization on the structural and mechanical properties of the hydrogels. We show that both differentiated and non-differentiated neuroblastoma cells and long-term self-renewing neuroepithelial stem cells (lt-NES) remained viable in the hydrogels. The hydrogels also had a protected effect on lt-NES during syringe ejection and bioprinting. In paper IV, we used HA-based hydrogels modified with peptides sequences derived from fibronectin and laminin for culture of fetal primary astrocytes (FPA). We explored both the interactions between the hydrogels and FPA and possibilities to 3D bioprint FPAs. Finally, in paper V, we developed HA-nanocellulose composite hydrogels with the aim to increase printing fidelity and enable fabrication of multi-layered bioprinted structures without the use of a support bath. In addition to HA, we used wood-fibre derived nanocellulose (NC) to increase the viscosity of the bioink during the printing process. The developed biorthogonal and modular hydrogel systems provide a large degree of flexibility that allows for encapsulation and culture of different cell types and processing using different techniques, which can contribute to further exploration of fabrication of biologically relevant tissue and disease models.
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| 5. |
- Naeimipour, Sajjad, 1987-
(författare)
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Modular Enzyme-Responsive Polysaccharide-Based Hydrogels for Biofabrication
- 2023
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Engineered human tissue and disease models can decrease the cost and time of developing new drugs and treatments, facilitate personalized medicine, and eliminate the need for animal models that poorly represent the human body and are ethically problematic. However, the current conventional cell expansion methods using 2D culture flasks cannot enable the development of such complex multi-cellular 3D models. In general, hydrogels are considered promising materials that can make the biofabrication of tissue models possible. Hydrogels are highly hydrated materials comprised of either synthetic or naturally derived polymers, or a combination of both, and can form an environment mimicking the biomacromolecular network surrounding cells in the body. This network of biopolymers, known as extracellular matrix (ECM), is comprised of proteins such as collagen, laminin, fibronectin, and polysaccharides such as hyaluronan (HA), heparan, keratan, and chondroitin sulfate. The design of hydrogels representing the physical and biochemical properties of the ECM and which can be used for biofabrication is challenging but of increasing interest due to the rapid progress in the development of 3D and 4D bioprinting techniques. As the ECM properties differ between various tissues and disease conditions and change over time, a dynamic modular hydrogel system is needed to that can be optimized for each cell and tissue type. This thesis aims to develop modular enzyme-responsive polysaccharide-based hydrogels for 3D cell culture and biofabrication. The natural polysaccharides, hyaluronic acid (HA) and alginate (Alg) were used as the main backbone in the hydrogels developed in this thesis. HA was modified by conjugating bicyclo[6.1.0]non-4-yne (BCN) to the backbone to form HA-BCN-based hydrogels by a bioorthogonal strain-promoted alkyne-azide cycloaddition. The click reaction between BCN and azide groups allowed for modulating the biochemical and mechanical properties of the HA-BCN hydrogels. HA-BCN was further decorated with peptides to explore peptide folding and dimerization-mediated dynamic cross-linking and biofunctionalization. This system was further used to explore possibilities to dynamically alter the properties of 3D bioprinted structures, mimicking the biomineralization process in bone tissue. In a different study, a tumor model comprising fibroblast and breast cancer cells (MCF7) was bioprinted using HA-BCN cross-linked by matrix metalloporotease (MMP) cleavable and PEG-diazide MMP-resistant cross-linkers, demonstrating the synergistic relationship between hydrogel degradability and cancer cell growth, intensified by the presence of fibroblasts. The possibility of incorporating a conductive module into this hydrogel system was explored using the enzyme-assisted polymerization of ETE-S to form an interpenetrating conductive network inside HA-BCN hydrogel. The in situ and user-triggered polymerization of conductive ETE-S was demonstrated after 3D printing HA-BCN bioink containing ETE-S monomers into a lattice shape structure. We also demonstrated that cellulose nanofibrils (CNF) improved the printability of HA-BCN bioinks, and this hybrid bioink was used for printing self-standing cell-laden 3D structures. Besides these studies, a novel enzymatically triggered thiol-based chemistry was developed to address the unwanted oxidation of thiol-containing hydrogels and decrease the off-target thiol reactions during hydrogel synthesis and formation. Alginate containing sulfhydryl moieties, protected by an enzyme-labile Phacm group (AlgCP), was treated with penicillin G acylase and subsequently formed a disulfide cross-linked hydrogel. We studied the gelation kinetics and rheological properties of AlgCP and different modes of cross-linking by reversible disulfide bonds, a thiol-maleimide Micheale-type addition reaction, and ionic interactions between alginate and Ca2+ ions. MCF7 breast cancer cells cultured in the AlgCP hydrogels formed spheroids that could be harvested by GSH dissolution of the hydrogels. Finally, this novel chemistry enabled bioprinting of multi-material 3D structures with control over the printed structure's physiochemical properties, including the type and density of cross-linkers. Bioprinted fibroblasts formed extended morphology, and MCF7 cells formed spheroids in the bioprinted lattice structures. The hydrogel systems developed and explored in this thesis are modular and exhibit dynamic and tunable properties, and are applicable for a wide range of 3D cell culture and bioprinting applications. The hydrogels were either formed in response to the activity of an enzyme or remodeled by enzymes. Both enzyme-responsive HA-BCN and AlgCP hydrogel systems are promising bioinks for generating more elaborate and spatially defined cell-laden 3D structures whose features can be altered post-printing by cell-secreted and extrinsic reagents. These hydrogel-based toolkits can play a vital role in developing tissue and disease models that can make the drug discovery process faster, cheaper, and animal-free.
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| 6. |
- Rosenquist Lybecker, Jenny
(författare)
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Development of Injectable ECM-Polymer Hydrogels : Enhancing Corneal and Cardiac Repair with Encapsulated Extracellular Vesicles
- 2024
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- The field of medicine has traditionally relied solely on small molecular drugs and conventional surgical procedures. However, recent advancements have shifted the focus toward innovative approaches, such as tissue engineering and regenerative medicine, which aim to overcome the limitations of traditional treatments through personalized and precision medicine. This thesis investigates tissue repair strategies using minimally invasive methods, specifically through the application of injectable biomaterials with or without cell-derived therapeutic factors. To this end, a series of novel injectable hydrogels were developed, alongside protocols for the reliable isolation of extracellular vesicles. These components were then integrated to create injectable therapeutic hydrogels. In Paper I, an injectable collagen-based hydrogel was developed. The injectable hydrogel maintained its shape in aqueous buffers, was biodegradable by the body's own enzymes, and supported the encapsulation and attachment of model cells. In Paper II, the collagen hydrogel from Paper I was further developed for use as a corneal sealant in corneal perforations. The hydrogel retained its beneficial properties of being shape-holding, biodegradable, and supporting cell attachment. Additionally, it exhibited increased transparency and tunable mechanical properties through minor adjustments in stoichiometry. It also successfully withstood burst pressures exceeding normal intraocular pressure levels and demonstrated adhesive properties comparable to fibrin glue, while supporting corneal epithelialization. Altogether, showing promise as an injectable corneal sealant. In Paper III, extracellular vesicles from corneal epithelial cells were isolated, purified and characterized based on their size, morphology, surface protein pattern and protein content. Corneal epithelial extracellular vesicles are thought to promote wound healing which could be confirmed with a functional in vitro scratch assay. These therapeutic EVs were then encapsulated within the collagen hydrogel developed in Paper II. Release studies indicated that while a fraction of the EVs was released by simple diffusion, the majority were released on-demand through enzymatic degradation of the hydrogel. This presents a novel treatment strategy for corneal perforations by combining the tissue adhesive with therapeutic factors. In Paper IV, extracellular vesicles derived from induced pluripotent stem cells (iPSCs) were isolated and shown to promote cardiac function after injury. These EVs were encapsulated in viscous ECM-polymer solutions and injected into the left ventricle of mouse hearts, demonstrating that the viscous polymer solutions enhanced the retention of EVs in cardiac tissue over an extended period.In summary, this thesis investigates the potential of injectable hydrogels, both alone and in combination with extracellular vesicles, as treatments for corneal and cardiac injuries.
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| 7. |
- Eskilson, Olof, 1992-
(författare)
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Multifunctional Nanocellulose Composite Materials
- 2023
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Nanoparticles (NPs) are particles with more than one dimension between 1 and 100 nm. Because of their small size, they typically display different physical and chemical properties than the corresponding bulk materials. NPs have been used in many different applications, such as in electronics, optics, catalysis, and in biomedicine. Due to their colloidal nature, NPs are often immobilized on a solid substrate, such as glass or polymer-based materials, including biopolymers. Nanocellulose is a biopolymerbased nanomaterial that can be obtained from plants or bacterial biofilms. They can be processed into thin and highly hydrated films with high mechanical strength and can serve as a versatile substrate for NPs. Bacterial cellulose (BC) is also an interesting material for generating wound dressings. The combination of NPs and BC results in soft and flexible nanocomposites (BC-NPs) that can demonstrate novel properties and improve the functionality of wound dressings. BC-NP nanocomposites have previously been obtained by impregnating BC with the reactants needed for synthesis of the NPs and allowing the reaction to proceed in situ, inside and on the surface of the BC. This strategy limits the possibilities to control NP geometry and NP concentration and make synthesis of nanocomposites with more sophisticated compositions very challenging. In addition, the synthesis conditions used can potentially have negative effects on the properties of BC. The work presented in this thesis shows the possibility to produce well-defined, tunable BC-NP nanocomposites using self-assembly under very benign conditions that enable functionalization of BC with a wide range of different types of NPs. In addition to exploring the self-assembly process and the physical properties of these new BC-NP composites, several different applications were investigated. The functionalization of BC with gold nanoparticles (AuNPs) of different sizes and geometries was demonstrated. The resulting materials were used for development of a new sensor transduction technology, exploiting the optical response upon mechanical compression to detect biomolecules. BC-AuNP nanocomposites were also developed for monitoring of protease activity of wound pathogens, for catalysis, and for fabrication of ultra-black materials with unique absorption and scattering profiles of light in the visible and near infrared spectral range. In addition, the self-assembly process could be adopted for generating BC-mesoporous silica nanoparticles (MSNs) nanocomposite wound dressings. The resulting high surface area materials could be used as carriers for pH sensitive dyes. The pH-responsive BC-MSNs demonstrated adequate biocompatibility and allowed for monitoring of wound pH and for assessment of wound status. The strategies for functionalization of BC with inorganic NPs that was developed and explored in this thesis are highly versatile and allow for fabrication of a wide range of multifunctional nanocomposite materials.
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