Mechanics of biofunctionalised bioconducting microfibres for the treatment of spinal cord injury

Corridori, Ilaria

23 November 2021

Spinal cord injury causes the partial or total loss of the anatomical and functional continuity of the spinal cord tissue, leading to the damage of the organs controlled by nerves that branch off downstream the injury. This thesis analyses the mechanics of two possible treatments based on two different approaches: intraspinal microstimulation (ISMS) and tissue engineering. These two approaches have a common rationale, the delivery of electrical stimuli to the injured spinal cord. In the literature, the feasibility of the electrodes for ISMS is often limited to the analysis of stiffness. The mechanical validation of the device is then focused on the step after the in vivo implantation, considering the interplay with the surrounding tissue. In this work, the mechanical performance of an innovative intraspinal microstimulation device is evaluated thoroughly before the in vivo step, to avoid the waste of material, animals, and time. The study involves the characterisation of the single components (electrodes), prototypes, and possible failure mechanisms. A work on silk fibroin hydrogels for the regeneration of the spinal cord is also presented. Silk fibroin is a highly versatile material for biomedical purposes, and thus largely used in tissue engineering. Moreover, it has piezolectric properties subjected to micro and nanostructure. Given the proven benefits of electrical stimulation in the regeneration of the spinal cord after injury, different approaches studied in literature often require the use of external devices to generate electrical stimuli. This thesis aims to study the mechanical properties of silk fibroin hydrogels obtained by applying an electric field to silk fibroin solutions, to investigate the eventual increase of the microstructure orientation and consequent improvement of the piezoelectric effects of fibroin.

Thermoelectric Properties of Carbon Nanotubes (CNT) - Fibroin Composites

Enyinnaya, Chukwuka

January 2022

No description available.

Materials Science

Seebeck Coefficient

Bombyx mori

single-walled carbon nanotubes

fibroin

bio-polymer

junction charge transport

Fatty Acid Amides and Their Biosynthetic Enzymes Found in Insect Model Systems

Anderson, Ryan L.

16 November 2018

A fatty acid amide is precisely as the name suggests: A fatty acid (CHn-COOH), in which the hydroxyl group of the carboxylic acid is displaced by an amine functional group from a biogenic amine (R-NH2), ultimately forming an amide bond. Furthermore, these fatty acid amides can be composed of a variety of different acyl chain lengths donated by the fatty acid and a myriad of different biogenic amines. Thus, these molecules can be subdivided in a number of different ways including the separation of short chain (acetyl to heptanoyl) and long chain (palmitoyl to arachidonoyl) and also based off the biogenic amine type. The long chain fatty acid amides quickly gained the interest of the scientific community through the discovery of anandamide (N-arachidonoylethanolamide), which was found to be the endogenous ligand for the cannabinoid receptor-1 (CB1) found in the mammalian brain. This particular neural molecule is an N-acylethanolamide, which is one specific classification of long chain fatty acid amide. However, there exist other types of long chain fatty acid amides including the N-acylglycines, primary fatty acid amides (PFAMs) and N-acylarylalkylamides. Yet, despite the type of fatty acid amide, it has been shown many of these types of molecules are synthesized using a type of N-acyltransferase. These N-acyltransferases are believed to be members of the GCN5-related superfamily of N-acyltransferases (GNAT), which share the feature of being able to accept acyl-CoA thioester substrates. This dissertation will discuss and demonstrate the extraction of all types of the aforementioned classifications of long chain fatty acid amides but will have a particular focus on the N-acylarylalkylamides. Elucidating more about the biosynthetic pathways and metabolic routes of the long chain fatty acid amides could lead to the development of potential therapeutics and pest control agents. We have determined Drosophila melanogaster arylalkylamine N-acyltransferase like 2 is responsible for the in vivo biosynthesis of N-acyldopamines. We have also demonstrated Bombyx mori is another suitable model systems for the study of long chain fatty acid amides, as three insect arylalkylamine N-acyltrasnferase from Bombyx mori (Bm-iAANAT) were found to share some homology in primary sequence (25-29%) to AAANTL2 in Drosophila melanogaster. We show herein that one of these enzymes is able to catalyze the formation of long chain N-acylarylalkylamides in vivo. The change in the transcription of these enzymes was tracked to try and understand if these enzymes serve a focused purpose in the physiological development of the insect. If it is found one of these Bm-iAANAT are crucial for growth, it may elucidate a general function of the enzyme, which may be able to inhibit growth of specific insects that are known pests, while not targeting endangered insects like Apis melliferra (honey bee). Understanding this would help in the eventual creation of targeted insecticides on specific insect pests Furthermore, a novel panel of fatty acid amides was characterized and quantified in extracts from this organism via LC-QToF-MS, ultimately showing it is very possible the Bm-iAANATs are performing this catalysis in vivo.

arylalkylamine n-acyltransferase

Bombyx mori

Drosophila melanogaster

knockdown

Gal4

upstream activator sequence

N-acylarylalkylamides

SiRNA

Biochemistry

Cell Biology

Étude de la microstructure et du comportement mécanique de la fibre de soie

Jauzein, Vincent

04 November 2010

Les polymères naturels présentent de plus en plus une alternative crédible pour de nombreuses applications techniques et biomédicales. Ils possèdent des qualités de modularité, de durabilité, souvent de biocompatibilité, qui leurs sont propres. Mais la compréhension détaillée des mécanismes qui gouvernent le comportement de tels matériaux est difficile et reste souvent incomplète. Cette étude a cherché à mieux comprendre le lien qui existe entre le comportement mécanique et la microstructure pour la fibre de soie. Une caractérisation minutieuse du comportement mécanique a donc été effectuée par des moyens parfois originaux comme l'association entre une machine de traction et une observation en microscopie électronique. Il a ainsi été montré l'aspect composite du fil de soie industriel et l'importance des différents éléments constitutifs de la soie. Le comportement de la fibre a également été décrit dans différentes conditions atmosphériques d'humidité et de température. Cette caractérisation s'est accompagnée d'une description de la microstructure en utilisant des techniques telles que la diffraction aux rayons X et la spectrométrie Raman. Notamment, la spectrométrie Raman a pu être associée à une traction in situ. Ceci a permis d'établir des liens entre mécanique et microstructure. Il a ainsi été prouvé notre capacité à modifier la microstructure et le comportement mécanique de la soie par voie biotechnologique en modifiant le génome du Bombyx mori. Ce qui ouvre une nouvelle voie d'innovation prometteuse pour améliorer ce type de matériau. Enfin, une modélisation simple mais robuste basée sur une description physique du matériau a permis de valider les avancées faites quant à la compréhension de ce polymère. Le comportement en environnement contrôlé a été étudié. Ces résultats pourraient alimenter des études numériques sur des assemblages, plus proches du produit fini.

[SPI:MAT] Engineering Sciences/Materials

soie

microstructure

comportement mécanique

analyse multiéchelle

diffraction aux rayons X

microextensométrie Raman

Bombyx mori

araignée

Why and how is silk spun? : integrating rheology with advanced spectroscopic techniques

Boulet-Audet, Maxime

January 2013

This thesis investigates the mechanisms behind natural silk spinning by integrating rheology, spectroscopy and small angle scattering to better understand this process and to guide our efforts towards mimicking Nature’s ways of producing high performance fibres. As a result of natural selection, arthropods such as spiders and moths have evolved the ability to excrete silk proteins in a highly controlled manner. Spun from liquid feedstocks, silk fibres are used ex vivo to build structures with mechanical properties currently unmatched by industrial filaments. As yet, relatively little attention has been directed to the investigation of spinning under biologically relevant conditions. To better understand how and why silk is spun, this thesis bridges the gap between liquid silk flow properties and structure development. To directly connect the two, I have developed and deployed novel experimental platforms that combine infrared spectroscopy and small angle scattering with rheology. This approach has clarified long-standing ambiguities on the structural root of silk’s apparently complex flow properties. Small angle scattering revealed the length scales involved in the flow induced solidification under a range of spinning conditions. Mo reover, infrared spectroscopy offered a unique perspective into silk’s formation process immediately after excretion. In a similar manner to the post-extrusion tuning of the properties of partly solidified spider silk filaments, this thesis has revealed that silkworm silk fibres are far from completely formed once excreted. One might describe the filaments of mulberry silkworm as seeded molten polymers that form its hydrogen bonding network and crystallises slowly on site. Consequently, it enlightens that post-spinning conditions are equally paramount for silkworm silk, giving an explanation for the relatively poorer mechanical properties. The comparison of silks from a range of species, allowed this hypothesis to be extended to wild silkworm silk. My insights into spinning had the fortuitous repercussion of facilitating silk fibre solubilisation leading to the development of better artificial silk feedstocks flowing like native silks. With these findings, I believe we are now in an improved position to conceive artificial fibres with properties rivalling those of Nature.

591.5

Interactions microsporidies-insectes in vivo : dissémination de Nosema bombycis (Microsporidia) dans son hôte Bombyx mori (Lepidoptera) et caractérisation de protéines structurales majeures de N. bombycis impliquées dans l'invasion

Wang, Jian-Yang

02 March 2007

Nosema bombycis est un parasite obligatoire intracellulaire et eukaryoitique microsporidia apparenté aux champignons. Cette microsporidie est l'agent responsable de la pébrine, maladie du ver à soie Bombyx mori qui inflige de sévères pertes économiques à la sériciculture mondiale. Nous avons étudié l'interactions N. bombycis-B. mori in vivo : l'infestation par N. bombycis démarre au niveau de l'épithélium intestinal antérieur, puis s'étend aux muscles et trachées adjacents. Les tissus plus distants sont ensuite infectés. Cependant, les réponses immune mélanisation et phagocytose, l'hémolymphe et les hémocytes sont les vecteurs de la dissémination de N. bombycis dans son hôte. Nous avons développé une approche protéomique pour identifier des protéines de tube polaire (PTP). Trois PTPs ont été caracterisés par immunocytochimie MET et MS/MS. Des motifs de séquence peptidique ont pu en être déduits par les programmes Peaks Online et DeNovoX, puis évalués par algorithmes Mascot et Sequest

Microsporidia

Nosema bombycis

Bombyx mori

dissémination in vivo

hémolymphe et hémocytes

profils protéomiques bidimensionnels

séquençage MS/MS de novo

protéines de tube polaire

AGREGATION DE PROTEINES DE SOIE DANS UN ENVIRONNEMENT MICROFLUIDIQUE

Martel, Anne

10 September 2008

La soie est un biopolymère synthétisé par certains arthropodes. Cette fibre est constituée de protéines arrangées en une microstructure semi-cristalline et possède d'intéressantes propriétés mécaniques. L'axe principal de ce travail de thèse concerne la compréhension du processus de formation de la fibre de soie. La soie de Bombyx mori a été choisi comme modèle. Sa protéine, nommée Fibroïne, a été utilisée pour produire une fibre dans une cellule microfluidique construite pour mimer l'appareil de filage du ver à soie. Le processus de formation de la soie a été suivi par des techniques de diffusion des rayons X (SAXS et WAXS) et par spectroscopie Raman. Elle débute par une étape d'agrégation. La taille des agrégats est de l'ordre de 100 nm. Dans ces particules, la Fibroïne est sous une forme compactée. Cette agrégation est suivie d'une phase de compaction des agrégats. Plus tard, à une échelle de temps de quelques heures, la Fibroïne subit une transition conformationnelle depuis une structure principalement amorphe (Silk I) vers la structure caractéristique de la soie naturelle (Silk II). Ce processus est proposé comme un modèle de la formation de la fibre de soie in vivo. Le second axe de ce travail est orienté vers la connaissance des propriétés physiques de la soie naturelle de B. mori. Sa résistance aux hautes températures est étudiée d'un point de vue structural, moléculaire et mécanique. L'effet des hautes pressions sur la structure de la fibre de soie est aussi présentée.

[SDV] Life Sciences

Soie

Bombyx mori

Fibroïne

Microfluidique

diffusion des rayons X

SAXS

WAXS

spectroscopie Raman

hautes températures

hautes pressions

Natural and bioinspired silk spinning

Davies, Gwilym

January 2014

This thesis describes an investigation into silk spinning, with the objective of producing high performance silk fibres in the laboratory using a novel spinning device based upon observations on natural spinning glands and processes. After an in-depth literature review the work is reported in two sections: natural and artificial spinning. The literature provides fragmented data on different aspects of natural silk production, and artificial spinning has not yet reproduced fibres with the properties of native silk fibres, despite unfounded claims of biomimetic spinning. The first half of the thesis looks at natural silk spinning. The work started with a general study of the morphology of spider and silkworm spinning ducts: First, how the silk fibre develops as the dope flows through the gland; and second the relationship between silk fibre properties and both gland morphology and spinning speed. More detailed studies using histochemical and spectroscopic investigations showed that the silk ducts of the spider Nephila edulis and the silkworm Bombyx mori both contain β-chitin, despite an evolutionarily distant common ancestor. Finally, observations showed that the duct of N. edulis consists of alternating nanoporous discs, and FEA modelling indicated that the duct is optimised for mechanical integrity and permeability. The second half of the thesis describes the development of a spinning device that uses natural silk dope mainly taken from B. mori as feedstock. It begins with a description of the gradual development of the engineering aspects of the spinning device, to meet challenges raised during the spinning investigation. The development of a centrifugal capillary rheometer, for practical quantitative insights into rheological processes is then presented. Finally the spinning investigation is reported: first, the screening of spinning in glass capillaries based upon natural gland dimensions and flow rates, which have been shown to induce fibrillation in silk dope in a rheometer, and also included initiation of instability through heat applied along the capillary; second, the final spinning evaluation, using lessons learned from all the screening trials throughout the project, but also including a key development of a hydrophobic coating on the capillary tip to inhibit droplet formation and massively increase the process stability and ease of fibre production. The main conclusions from this work are that good silk fibre cannot be spun by flow shear stress alone; and, that heat instability induces indiscriminate gelation of the silk, whose disordered molecular structure gives poor silk fibre properties. The body of work behind these conclusions provides fundamental background information and new insights that will contribute to the next stages of development of artificial silk spinning, from obtaining a better understanding of the biology of natural spinning glands to the engineering difficulties of implementing the bioinspired principles.

677

家蚕の代謝特性とその有効利用

山下, 興亜, 古賀, 克己, 江口, 正治, 佐々木, 卓治, 柳沼, 利信, 小林, 迪弘, 森島, 伊佐夫, 大西, 英爾, 小山内, 実

03 1900

科学研究費補助金 研究種目:総合研究(A) 課題番号:60304024 研究代表者:山下 興亜 研究期間:1985-1987年度

カイコ

カルモジュリン

卵黄たんぱく質

Bombycosterol

プロテアーゼインヒビター

休眠

ボンビコステロン

エクジステロイド

ホルモン

Sorbitol

精子

アルギニシカスケード

プロテアーゼインヒビター

ソルビトール

Bombyx mori

Protease inhibitor

環状ヌクレオチド

Hormone

Cyclic nucleotide

ソルビトール

New DNA-Targeting Small Molecules as Potential Anticancer Agents and for in vivo Specificity toward Enhanced Silk Production

Ali, Asfa

January 2014

The thesis entitled “New DNA-Targeting Small Molecules as Potential Anticancer Agents and for in vivo Specificity toward Enhanced Silk Production” encompasses design, computational calculations, and syntheses of diverse small molecular scaffolds to explicitly target duplex and higher order DNA morphologies (G-quadruplex DNA). Some of these molecules have a potential as anticancer agents. Besides, an attempt has been made elucidate the importance of novel oligopyrrole carboxamides in the enhancement of silk yield, hence proving to a boon in the field of sericulture. The work has been divided into six chapters. Chapter 1. DNA Binding Small Molecules as Anticancer Agents Figure 1. DNA targeting by small molecules. Cancer has always been a dreadful disease and continues to attract extensive research investigations. Various targets have been identified to restrain cancer. Among these DNA happens to be the most explored one. A wide variety of small molecules, often referred to as “ligands”, has been synthesized to target numerous structural features of DNA (Figure 1). The sole purpose of such molecular design has been to interfere with the transcriptional machinery in order to drive the cancer cell toward apoptosis. The mode of action of the DNA targeting ligands focuses either on the sequence-specificity by groove binding and strand cleavage, or by identifying the morphologically distinct higher order structures like that of the G-quadruplex DNA. Chapter 2. Ligand 5, 10, 15, 20-tetra(N-methyl-4-pyridyl)porphine (TMPyP4) Prefers the Parallel Propeller-type Human G-Quadruplex DNA over its other Polymorphs The binding of ligand 5, 10, 15, 20-tetra(N-methyl-4-pyridyl)porphine (TMPyP4) with telomeric and genomic G-quadruplex DNA has been extensively studied. However, a comparative study of interactions of TMPyP4 with different conformations of human telomeric G-quadruplex DNA, namely parallel propeller-type (PP), antiparallel basket-type (AB), and mixed hybrid-type (MH) G-quadruplex DNA has not been done. We considered all the possible binding sites in each of the G-quadruplex DNA structures and docked TMPyP4 to each one of them. The resultant most potent sites for binding were analyzed from the mean binding free energy of the complexes. Molecular dynamics simulations were then carried out and analysis of the binding free energy of the TMPyP4-G-quadruplex complex showed that the binding of TMPyP4 with parallel propeller-type G-quadruplex DNA is preferred over the other two G-quadruplex DNA conformations. The results obtained from the change in solvent excluded surface area (SESA) and solvent accessible surface area (SASA) also support the more pronounced binding of the ligand with the parallel propeller-type G-quadruplex DNA (Figure 2). Figure 2. Ligand TMPyP4 prefers parallel propeller-type G-quadruplex DNA morphology. Chapter 3. A Theoretical Analysis on the Selective Stabilization of Intermolecular G-quadruplex RNA with a bis-Benzimidazole Ligand EtBzEt over TMPyP4 in K+ Environment Ever since the discovery of G-quadruplex RNA, a constant urge exists to target these higher order RNA conformations. These structures play a significant role in the transcriptional and translational mechanism. Herein we have determined the mode and extent of association of certain G-quadruplex DNA binding bisbenzimidazole ligand (EtBzEt) in comparison to a known porphyrin ligand (TMPyP4). We have performed docking studies of the known G-quadruplex DNA binding ligands with the parallel propeller G-quadruplex RNA (PPR) to determine the most potent binding conformation which showed EtBzEt to be a better RNA binder than others. Furthermore, a molecular dynamics (MD) simulation (6 ns) was performed for the most stable docked complex in explicit solvent environment. The role of K+ ions, Hoogsteen hydrogen bond formation and backbone dihedral angle between the tetrads were carefully analyzed during the entire simulation run to determine the stability of each ligand associated PPR complex. All the analyses conclusively showed that while TMPyP4 merely stabilized the PPR, the ligand EtBzEt stabilized PPR very efficiently (Figure 3). Figure 3. Stabilzation and destabilization by EtBzEt and TMPyP4, repectively. Red and green ovals represent EtBzEt and TMPyP4, repectively. Chapter 4A. Design and Synthesis of New DNA Binding Fe(III) and Co(II) Salen Complexes with Pendant Oligopyrrole Carboxamides Extensive research on these oligopyrrole carboxamides has shown their specificity toward AT-rich sequences with high binding affinity. Here we have designed and synthesized Fe (III)-and Co (II)-based salen complexes attached with minor groove targeting oligopyrrole carboxamide side-chains (Figure 4). While the ligands showed excellent activity toward DNA damage, they also exhibited high affinity toward the minor grooves of the ds-DNA. This was also reflected in the high efficiency of the ligands toward cancer cell cytotoxicity. Further studies revealed that the ligands resulted in prominent nuclear condensation and fragmentation thereby driving the cells toward apoptosis. The presence of metal coordinated salen moiety conjugated with positively charged pendants ending with minor groove binding oligopyrrole carboxamides might have resulted in the increased activity of the ligands toward DNA targeting and cancer cell death. Figure 4. Chemical structures of the ligands used in this study. Chapter 4B. Design and synthesis of novel oligopyrrole based salen metal complexes and their efficiency toward stabilization of G-quadruplex DNA DNA targeting has been the key strategy toward the restriction of cancer cell proliferation. In a similar effort, we have designed and synthesized novel salen based Ni(II) and Pd(II) metal complexes with positively charged flanking side-chains comprising attached N-methylpyrrole carboxamides of varying lengths (Figure 5). The ligands showed efficient stabilization of the G-quadruplex DNA morphologies, with specificity over the duplex DNA. Sufficient inhibition of the telomerase activity was observed by the TRAP-LIG assay which was ascertained by the prominent restriction of cancer cell proliferation in the long-term cell viability assay. The ligands exhibited condensation and fragmentation of the nucleus when observed under confocal microscopy which is indicative of the cells undergoing apoptosis. Further annexin V-FITC and PI dual staining showed apoptosis to be the mechanistic pathway underlying the cancer cell cytotoxicity by the ligands. Modeling studies clearly showed the stacking of the salen moiety over the G-tetrads with the association of the pendant oligopyrrole carboxamide units to the grooves. Figure 5. Chemical structures of the ligands used in this study. Chapter 5A. Role of Metal Ions in Novel Fluorescein based Salen and Salphen Complexes toward Efficient DNA Damage and their Effect on Cancer Cells Metal ions play an important role toward DNA damage and numerous ligands have been synthesized for their use in anticancer therapy. Herein, we have designed and synthesized Fe(III) and Co(II) based salen/salphens by bridging two fluorescein moieties with varying spacers (Figure 6). Although the ligands exhibit dual binding mode, the more flexible salen ligands prefer to associate to the minor groove of the DNA while the relatively rigid salphen ligands show greater intercalation. The biophysical experiments reveal better binding affinity of the salphens toward duplex DNA as compared to the salen ligands. The metal coordination resulted in efficient DNA cleavage of plasmid at low ligand concentrations. The ligands also showed cancer cell cytotoxicity, cellular internalization with apoptosis as the proposed mechanism for cell death. Figure 6. Chemical structures of the salen and salphen ligands used in this study. Chapter 5B. Fluorescein based Salen and salphen Complexes as stabilizers of the Human G-quadruplex DNA and Promising Telomerase Inhibitors Metal based salen complexes have been considered as an important scaffold toward targeting of DNA structures. In the present work we have designed and synthesized nickel(II)-and palladium(II)-salen and salphen ligands by using fluorescein as the backbone to provide an extended aromatic surface (Figure 7). The ligands exhibit sufficient affinity toward the human telomeric G-quadruplex (G4) DNA in preference to the duplex DNA and also exhibit promising inhibition of telomerase activity. This is ascertained by their potency in the long-term cell viability assay which shows significant cancer cell cytotoxicity in presence of the ligands. Confocal microscopy showed cellular internalization followed by nuclear localization. Considerable population at the sub-G1 phase of the cell cycle showed cell death via apoptotic pathway. Figure 7. Chemical structures of the ligands used in this study. Chapter 6. Knockdown of Broad-Complex Gene Expression of Bombyx mori by Oligopyrrole carboxamides Enhances Silk Production Bombyx mori (B. mori) is important due to its major role in the silk production. Though DNA binding ligands often influence gene expression, no attempt has been made to exploit their use in sericulture. The telomeric heterochromatin of B. mori is enriched with 5′-TTAGG-3′ sequences. These sequences were also found to be present in several genes in the euchromatic regions. We examined three synthetic oligopyrrole carboxamides that target 5′-TTAGG-3′ sequences in controlling the gene expression in B. mori (Figure 8). The ligands did not show any defect or feeding difference in the larval stage, crucial for silk production. The compounds caused silencing of various isoforms of the broad-complex transcription factor and cuticle proteins which resulted in late pupal developmental defects. This study shows for the first time use of oligopyrrole carboxamide drugs in controlling gene expression in B. mori and their long term use in enhancing silk production. Figure 8. Chemical structures of the ligands used in this study (top) and increased cocoon size on ligand treatment.

DNA Targeted Samll Molecules

DNA Binding Anticancer Drugs

G-Quadruplex DNA

Oligopyrrole Carboxamides

DNA Targeting Cancer Drugs

Anticancer Drugs

Bombyx Mori Gene Expression

Molecular Targeted Anticancer Agents

Organic Chemistry