Surface Enhanced Raman Spectroscopy as a Tool for Waterborne Pathogen Testing

Wigginton, Krista Rule

25 November 2008

The development of a waterborne pathogen detection method that is rapid, multiplex, sensitive, and specific, would be of great assistance for water treatment facilities and would help protect water consumers from harmful pathogens. Here we have utilized surface enhanced Raman spectroscopy (SERS) in a sensitive multiplex pathogen detection method. Two strategies are proposed herein, one that utilizes SERS antibody labels and one that measures the intrinsic SERS signal of organisms. For the SERS label strategy, gold nanoparticles are conjugated with antibodies specific to Cryptosporidium parvum and Giardia lamblia and with organic dye molecules. The dye molecules, rhodamine B isothiocyanate (RBITC) and malachite green isothiocyanate (MGITC) were surface enhanced by the gold nanoparticles resulting in unique fingerprint SERS spectra. The SERS label method was successful in detecting G. lamblia and C. parvum simultaneously. The method was subsequently coupled with a filtration step to both concentrate and capture cysts on a flat surface for detection. Raman mapping across the filter membrane detected ~95% of the spiked cysts in the optimized system. In the second type of strategy, intrinsic virus SERS signals were detected with silver nanoparticles for enhancement. Principal component analysis performed on the spectra data set resulted in the successful differentiation of MS2 and PhiX174 species and also for the differentiation of viable virus samples and inactivated virus samples. / Ph. D.

surface enhanced Raman spectroscopy

Cryptosporidium parvum

drinking water

Giardia lamblia

bacteriophage

pathogen detection

The relationship between environmental conditions and CRISPR adaptation in Streptococcus thermophilus / Environmental DNA and the context of CRISPR adaptation

Croteau, Félix R.

January 2024

The CRISPR-Cas system is a bacterial adaptative immune system which protects against infection by phages: viruses that infect bacteria. To develop immunity, bacteria integrate spacers — fragments of the invading nucleic acids — into their CRISPR array to serve as the basis for sequence-targeted DNA cleavage. However, upon infection, phages quickly take over the metabolism of the bacteria, leaving no time for the bacteria to acquire new spacers, transcribe them and use them to cut the invading DNA. To develop CRISPR immunity, bacteria must be safely exposed to phage DNA. Phage infection releases eDNA which could be involved in the development of CRISPR immunity. Using S. thermophilus and phages 2972 and 858 as a model for CRISPR immunity, I show that eDNA is crucial to the development of optimal CRISPR immunity, as generation of phage-immune bacterial colonies decrease with eDNA digestion. Furthermore, it is phage eDNA specifically that impacts CRISPR immunity since its addition increases the generation of phage-immune colonies. I also show that the effect of eDNA is phage-specific, sequence specific and can even be traced to a region of the genome covering the early-expressed genes which differ between phages 2972 and 858. While the acquisition of CRISPR spacers is not random and while the supplementation of eDNA influences that bias, eDNA is not used as a source of genetic information for spacer acquisition. This suggests that the effect of eDNA involves a new mechanism of phage resistance. Moreover, the effect of eDNA is highly dependent on environmental conditions as variation in media suppliers are sufficient to interfere with this effect. These results link environmental conditions, specifically eDNA, to the CRISPR-Cas system, providing a better understanding of the context of the emergence of CRISPR immunity and could inform our understanding of the mechanisms through which bacteria detect the presence of phages before infection. / Thesis / Doctor of Philosophy (PhD) / Phages are viruses that can infect and kill bacteria with a 99.9999% success rate. To defend themselves, bacteria have evolved an adaptive immune system called the CRISPR-Cas system. This system uses a piece of DNA, called a spacer, that matches the phage to destroy it. However, in order to use their CRISPR-Cas system, they need to obtain this spacer. Given how dangerous phages are, how bacteria acquire this spacer is a mystery. My project investigates the possibility that bacteria use DNA floating in the environment to vaccinate themselves against phages before ever encountering them. In this thesis I show that DNA floating in the environment helps bacteria acquire these spacers. I also show that it is specific sections of phage DNA that helps bacteria. This shows that bacteria can use their environment to defend themselves against threats before they even happen.

CRISPR

Bacteriophage

Streptococcus thermophilus

competence

environmental DNA

eDNA

phage

bacteria

adaptation

New Phages, New Insights: Diversity in Phage Research Leads To Impactful Phage Therapy Outcomes

Harry Jack Ashbaugh (18858763)

22 June 2024

<p dir="ltr">Bacteriophages are viruses that infect, replicate in, and kill bacteria. In industries that utilize microbes for production, like <i>E.coli</i> in the production of insulin or <i>A. globiformis</i> in the production of cheese, bacteriophages can pose a huge threat to manufacturing. However, bacteriophages aren’t entirely detrimental: we can use the destructive nature of bacteriophages to kill bacterial infections in the human body. This process is known as phage therapy, and while it isn’t a new concept, it is being seen as an increasingly necessary alternative to traditional antibiotics due to the increasing rise of antimicrobial resistance. Because bacteriophages have an entirely different mechanism of destroying bacteria, they can be used in tandem with traditional antibiotic regimens to help wipe out infections. Also, phages have a highly specific host range, meaning that an injection of a certain type of phage will only infect the bacteria it is targeting, sparing important gut microbes.</p><p dir="ltr">The search for new phages to treat infections has resulted in the discovery of over 25,000 actinobacteriophages, with about 4898 of them being sequenced. This is extremely important and necessary, but 49% of these sequenced phages are all mycobacteriophages. This bias towards mycobacteriophages is likely because they infect the genus mycobacterium, where the deadly <i>M. tuberculosis</i> resides. The discovery of new phages using less studied hosts results in novel phages that exhibit rarely seen morphologies, phenotypes, and genotypes. This leads to a better overall understanding of the phage proteome and can lead to new breakthroughs in phage therapy.</p><p dir="ltr">The purpose of this research is to study the differences between different types of phages and try to determine the impact it may have on phage therapy. This thesis is divided into three chapters. In the first chapter, novel phages from different hosts, including <i>M. smegmatis</i> and <i>A. globiformis</i>, were discovered and annotated, and the differences between them were characterized. The discovery of arthrobacteriophages immediately resulted in rare and previously unseen phage characteristics. In the second chapter, proteomic mass spectrometry data of various diverse mycobacteriophages was analyzed to determine differences. Despite being from multiple clusters and lifecycles, the expression data had more similarities than differences. In the third chapter, an alternative method of extracting DNA from phages is explored to determine the result of discrepancies in gel quality from <i>M. smegmatis</i> and <i>A. globiformis.</i><i> </i>Although a large amount of nucleic material was derived, it was not stable DNA and was unsuitable for use. The reason for poor gel quality is still unknown.</p>

Bioinformatic methods development

Proteomics and metabolomics

Virology

phage therapy and biotechnology

bacteriophage engineering

AMechanistic and Chemistry-Focused Approach Towards the Development of Novel Covalent Binding Cyclic Phage Libraries:

Nobile, Vincent

January 2022

Thesis advisor: Jianmin Gao / Covalent drugs present a unique situation in the clinical world. Formation of a covalent bond between a drug molecule and its target protein can lead to significant increases in a number of desirable traits such as residence time, potency, and efficacy of a drug. From a kinetic perspective, the formation of a covalent bond between a drug and its target functionally eliminates the dissociation rate (koff) of the compound, ensuring that the compound will stay engaged with its target. However, development of covalent drugs has been met with caution and concern, as an irreversible covalent bond forming on the wrong target can have disastrous results, so specificity is of the utmost importance. One option for increasing specificity is by linking a covalent binding electrophile, or warhead, to a peptide. Peptide-based therapeutics have already been shown to serve as effective protein-targeting modalities with high specificity, a specificity that would greatly benefit covalent drugs. Phage display is a powerful technique for the discovery of selective peptides which utilizes the screening of vast libraries of randomized peptides to identify strong binders. This technology has been used to discover a large number of protein-targeting peptides, but also a smaller number of cyclic, covalent binding peptides that function as enzymatic inhibitors. Herein, this study aimed to explore the idea of adding covalent-binding functionality to phage libraries in novel ways and expand upon the scope of proteins that can be targeted with phage libraries containing covalent libraries. We sought to develop a mechanistic and chemical understanding of the interactions between bacteriophage and chemical warheads to best understand both the limits and the potential of this technology. In order to best understand the relationship between chemical warhead and phage particle, a model system was developed based on the M13KE pIII protein. It was found that the extracellular N-terminal domains of this protein could be expressed and purified in low yields in bacterial cells and that these domains would behave similarly in solution as in the membrane of the M13KE bacteriophage. With this protein in hand, experiments previously performed using small, cysteine containing peptides, could be performed on a full protein to mimic the phage labeling environment. This protein was used to identify efficient cysteine crosslinkers, most notably dichloroacetone (DCA) and bis-chlorooxime (BCO). The pIII protein system was then used to study the viability of bifunctional warhead molecules containing a covalent warhead and a cysteine crosslinker. Based on preliminary analyses with the pIII protein, aryl sulfonyl fluoride was chosen as a novel warhead candidate that warranted further pursuit. Kinetic NMR studies verified that aryl sulfonyl fluoride was capable of forming covalent bonds with phenols under phage labeling conditions. Labeling experiments analyzed with LC/MS seemed to indicate a degradation of the warhead. However, as the source of the degradation was not able to be determined, it was decided that various affinity assays would be used to identify if phage could be labeled with an aryl sulfonyl fluoride-DCA conjugate. Both streptavidin-bead pulldown assays and ELISA assays were used, however both assays yielded results that could not conclusively verify the integrity of the warhead. During phage labeling experiments, a phenomenon was noted that phage titers after modification showed a 2-3 order of magnitude drop in phage count. Covalent modification of phage beyond what is intended could have troubling consequences for all covalent phage libraries, and so a more in-depth approach was taken to identify and better understand phage toxicity as it relates to covalent warheads. As a model, a well-studied diazaborine-mediated warhead with a slow dissociation rate was selected and used in a range of phage toxicity screenings. Despite statistical fluctuations between trials, toxicity screenings using this warhead served to highlight a unique concern for bifunctional covalent warheads. A concentration-dependent toxicity can be seen in phage incubated with bifunctional small molecules that is not present when incubated with the monofunctional equivalents. The presence of this toxicity even towards a phage with no free thiols highlights a unique challenge of off-target labeling within phage particles that, if solved, could provide the next significant step towards developing novel covalent phage libraries. / Thesis (MS) — Boston College, 2022. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Bacteriophage

Covalent Drugs

Covalent Phage Libraries

Cyclic Peptides

Cyclic Phage Libraries

Phage Display

Identification of broad host range phage that antagonize multidrug resistant Pseudomonas aeruginosa and their therapeutic potential to restore antibiotic susceptibility among these pathogens

Lake, Alexandra E.

12 August 2020

No description available.

Biology

Biomedical Research

Health

Microbiology

Therapy

phage

phage therapy

bacteriophage

bacteriophage therapy

Pseudomonas aeruginosa

multidrug resistance

antimicrobial resistance

synergy between antibiotics and phage

synergy between phage and antibiotics

antibiotic re-susceptibility

drug resistance

The type I-E CRISPR-Cas system : Biology and applications of an adaptive immune system in bacteria

Amlinger, Lina

January 2017

CRISPR-Cas systems are adaptive immune systems in bacteria and archaea, consisting of a clustered regularly interspaced short palindromic repeats (CRISPR) array and CRISPR associated (Cas) proteins. In this work, the type I-E CRISPR-Cas system of Escherichia coli was studied. CRISPR-Cas immunity is divided into three stages. In the first stage, adaptation, Cas1 and Cas2 store memory of invaders in the CRISPR array as short intervening sequences, called spacers. During the expression stage, the array is transcribed, and subsequently processed into small CRISPR RNAs (crRNA), each consisting of one spacer and one repeat. The crRNAs are bound by the Cascade multi-protein complex. During the interference step, Cascade searches for DNA molecules complementary to the crRNA spacer. When a match is found, the target DNA is degraded by the recruited Cas3 nuclease. Host factors required for integration of new spacers into the CRISPR array were first investigated. Deleting recD, involved in DNA repair, abolished memory formation by reducing the concentration of the Cas1-Cas2 expression plasmid, leading to decreased amounts of Cas1 to levels likely insufficient for spacer integration. Deletion of RecD has an indirect effect on adaptation. To facilitate detection of adaptation, a sensitive fluorescent reporter was developed where an out-of-frame yfp reporter gene is moved into frame when a new spacer is integrated, enabling fluorescent detection of adaptation. Integration can be detected in single cells by a variety of fluorescence-based methods. A second aspect of this thesis aimed at investigating spacer elements affecting target interference. Spacers with predicted secondary structures in the crRNA impaired the ability of the CRISPR-Cas system to prevent transformation of targeted plasmids. Lastly, in absence of Cas3, Cascade was successfully used to inhibit transcription of specific genes by preventing RNA polymerase access to the promoter. The CRISPR-Cas field has seen rapid development since the first demonstration of immunity almost ten years ago. However, much research remains to fully understand these interesting adaptive immune systems and the research presented here increases our understanding of the type I-E CRISPR-Cas system.

CRISPR

CRISPR-Cas

virus defense

bacteria

bacteriophage

adaptation

spacer integration

interference

gene silencing

fluorescent reporter

Escherichia coli

The Sensitivity of Pseudomonas Agar Plaque Assay in the Isolation of Bacteriophage Φ6 in the Environment: A pilot study

Sunmonu, Olasunkanmi

12 May 2017

Background: Bacteriophage Φ6 is a lipid-enveloped dsRNA bacteriophage. The limitations in our knowledge of how this bacteriophage occurs in the environment are limited by non-selective isolation techniques. Research on finding phages in the environment in the past has employed the Double Agar Layer (DAL) plaque assay using Tryptic Soy Agar (TSA), a non-selective media. The bacterial host for bacteriophage Φ6 is Pseudomonas syringae. In this study, we tested Pseudomonas Agar, a selective media that suppresses the growth of bacteria except Pseudomonas species, in the standard double agar layer plaque assay for Φ6. Methods: DAL plaque assays were performed to determine the sensitivity of both Tryptic Soy Agar (TSA) and Pseudomonas Agar (PA) for determining the titer of pure bacteriophage Φ6 stocks. We used Pseudomonas syringae (HB10Y) as the host, and the plaque formation on both agars was compared. Following the evaluation of PA with pure Φ6 stocks, PA effectiveness for Φ6 isolation from environmental samples was tested in spiked waters obtained from irrigation ponds at an agricultural farm. Results: Comparison of TSA and PA using pure Φ6 cultured in the laboratory and spiked environmental samples showed that PA agar can detect bacteriophage Φ6 as well as the standard DAL assay using TSA. On PA, formation of clear visible plaques comparable to the plaques formed using TSA was observed. Conclusions: Pseudomonas Agar can be used for the isolation of bacteriophage Φ6 in environmental samples. This may enhance the detection of these phages in the environment.

Bacteriophage Φ6

Double Agar Layer

DAL plaque assay

Pseudomonas syringae

Tryptic Soy Agar - TSA

Pseudomonas Agar - PA

Hybrid colloidal molecules from self-assembly of viral rod-like particles / Molécules colloïdales par auto-assemblage de virus anisotropes et de nanoparticules métalliques

Wu, Cheng

06 September 2018

Dans cette thèse, l’auto-assemblage en molécules colloïdales de virus en forme de filament, les bactériophages M13, est étudié. Comme première approche, l’affinité de la streptavidine pour la biotine ou un Strep-tag est utilisée et quantitativement comparée. Pour ce faire, des virus modifiés génétiquement, M13-AS, présentant des Strep-tag et des virus M13C7C chimiquement bioconjugués par de la biotine ont réagi via leur extrémité proximale avec des nanoparticules fonctionnalisées par de la streptavidine. Il en résulte la formation de molécules colloïdales en étoile, dont la valence ou nombre de virus par structure, peut être simplement contrôlée par l’excès molaire initial. Cependant, la stabilité de ces molécules colloïdales est limitée par la libération progressive et la dégradation de la streptavidine. Nous avons alors développé une seconde approche basée sur l’affinité soufre-métal, qui s’est avérée à la fois pratique expérimentalement et fiable. Grâce aux groupements disulfures présents sur les cystéines de la protéine P3, des nanoparticules métalliques peuvent se lier à l’extrémité des virus. Le caractère générique de cette méthode est vérifié en faisant varier la nature du métal des nanoparticules ainsi que la souche des virus, dont la sauvage. La valence des structures formées est déterminée en fonction de plusieurs paramètres, dont l’excès molaire initial, la taille des nanoparticules et la force ionique. Un modèle rendant compte des résultats expérimentaux a été élaboré, dont les principales variables sont la surface des nanoparticules et le diamètre effectif électrostatique des virus. Cette approche est étendue à la réalisation de diblocs colloïdaux hétéro bifonctionnels, utilisant les virus comme briques constitutives. Comme preuve de concept, des diblocs bicolores à base de virus sont obtenus par auto-assemblage et leur dynamique est étudiée à l’échelle du bloc élémentaire en microscopie optique de fluorescence. Ainsi, nous avons montré dans cette thèse la réalisation par auto-assemblage d’une nouvelle génération de molécules colloïdales, dont l’auto-organisation peut conduire à la formation de superstructures hiérarchiques hybrides de complexité croissante, potentiellement utiles en sciences des matériaux. / In this thesis, the self-assembly of rod-like viral particles, specifically the M13 bacteriophages, into colloidal molecules is studied. As the first method, the affinity of streptavidin to biotin or Strep-tag is used and quantitatively compared. In this case, both biologically engineered M13-AS displaying Strep-tags and chemically biotinylated M13C7C viruses have reacted with streptavidin activated nanoparticles via their functionalized proximal ends. This results in star-like colloidal molecules, whose valency – or number of viruses par structure – can be solely controlled by tuning the initial molar excess. However, the stability of these colloidal molecules is limited by streptavidin release and degradation. Thus, we develop the second method based on the sulfur—metal interactions, which is more convenient and reliable. Thanks to the exposed disulfide groups located at p3 proteins, metallic nanoparticles are able to bind to proximal ends of the M13 virus. The generic feature of this method is verified by using different metals and two virus strains including wt-M13. Afterwards, the control of the valency is explored by varying the initial molar excess, the nanoparticle size and the ionic strength. A quantitative model is built correspondingly, using the surface area of Au nanobead and the effective electrostatic diameter of the virus as variables, which accounts for the assembly of colloidal molecules with desired valencies. This method is further applied to assemble heterobifunctional diblocks by using filamentous viruses as building units. As a proof-of-concept experiment, bicolored diblocks are produced and tracked by each block simultaneously. Overall, we demonstrate the synthesis of a new generation of hybrid colloidal molecules, whose self-organization could serve as a promising means to create novel hierarchical biologic/inorganic superstructures that may find applications in materials science.

Bactériophage

Molécule colloïdale

Auto-Organisation

Nanoparticule d'or

Cystéine

Filamentous virus

Bacteriophage

Colloidal molecule

Self-Organization

Gold nanoparticle

Cysteine

Étude des propriétés de surface du bactériophage MS2 et du norovirus murin au cours de différents traitements d’inactivation / Evolution of surface properties of MS2 bacteriophage and murine norovirus during different inactivation treatments

Brié, Adrien

25 January 2017

Même si les traitements thermiques ou la désinfection par les oxydants ont démontré leur efficacité virucide, les mécanismes liés à la perte du caractère infectieux ne sont pas connus. Ceci pose un réel problème d’interprétation de la présence de génome viral en matière de risque infectieux dans les aliments. Ce travail de thèse a pour objectif d’étudier l’évolution des propriétés de surface (charge et hydrophobie) de virus modèles, bactériophage MS2 et norovirus murin, au cours de l’inactivation par la chaleur, l’hypochlorite de sodium et l’ozone. Pour nos deux virus, nous démontrons l’existence d’une température critique au-delà de laquelle la particule virale se déstructure en libérant son génome. Un simple traitement à la RNase permettrait alors de ne détecter que des virus infectieux par biologie moléculaire. Le traitement thermique implique aussi une augmentation de l’hydrophobie soulignant des modifications conformationnelles de la capside. L’hypochlorite de sodium ne modifie que peu les propriétés de surface mais des phénomènes d’oxydation ont lieu au niveau de la capside puisque la charge du bactériophage MS2 est légèrement modifiée. Ces modifications diminuent la résistance thermique du virus. Nous démontrons un effet synergique de l’hypochlorite de sodium et la chaleur sur le bactériophage MS2 (inactivation, RNase et hydrophobie). Quant à l’ozone gazeux, nous soulignons son intérêt pour le traitement virucide des aliments fragiles. Ainsi, ce travail précise les mécanismes d’inactivation des virus et ouvre de nouvelles perspectives tant pour discriminer les virus infectieux et non-infectieux que pour proposer l’exploration de nouveaux traitements technologiques / Although heat treatments or disinfections by oxidants have proven their virucidal efficiencies, mechanisms related to the loss of infectivity are not known. This statement could lead to a misinterpretation of the presence of viral genome on infection risk for humans in food matrices. This thesis aimed to study the evolution of surface properties (charge and hydrophobicity) for model viruses, bacteriophage MS2 and murine norovirus, during the heat, sodium hypochlorite and ozone inactivations. For both viruses, the existence of a critical temperature beyond which the viral particle was disrupted and released its genome was demonstrated. Simple treatment with RNase would then only detect infectious virus by molecular biology. The heat treatment also involved a transient increase in the hydrophobicity which highlighted conformational changes of the viral capsid. Sodium hypochlorite slightly modified the surface properties but oxidation phenomena occurred onto capsid since the bacteriophage MS2 charge has changed a little. These changes decreased the thermal resistance of the virus. Synergistic effects of both sodium hypochlorite and heat were observed on the inactivation of MS2 phages, the sensitivity of their genome to RNases and the increase in hydrophobicity of remaining infectious particles. Regarding gaseous ozone, we underlined its interest in the case of virucidal treatment of fragile food matrices. Therefore, this work specified the virus inactivation mechanisms and opened up new perspectives to discriminate infectious from non-infectious viruses but also to propose the exploration of new technological processes

Bactériophage MS2

Norovirus murin

Propriétés de surface

Traitements technologiques

Inactivation

MS2 bacteriophage

Murine norovirus

Surface properties

Industrial treatments

Inactivation

579.2

Estudo in vitro da ação antimicrobiana de bacteriófagos em canais radiculares infectados por isolados clínicos de Enterococcus faecalis / In vitro antimicrobial activity of bacteriophages in root canals infected with clinical isolates of Enterococcus faecalis

Paisano, Adriana Fernandes

14 March 2008

O uso de diferentes tipos de medicação intracanal para o controle do processo infeccioso, principalmente nos casos em que há presença de microrganismos resistentes às manobras de desinfecção, tem sido alvo de muitas pesquisas. A proposta deste estudo foi avaliar, in vitro, o efeito antimicrobiano de bacteriófagos específicos diante de cinco cepas de Enterococcus faecalis e a ação de um lisado híbrido polivalente na eliminação da infecção causada por essas cinco cepas da mesma espécie. Foram utilizados 37 dentes unirradiculares humanos, recentemente extraídos e de proporções aproximadas. As coroas foram removidas e os canais instrumentados até a lima tipo K de número 45. Os espécimes foram, então, esterilizados e utilizados em dois experimentos distintos. O primeiro experimento utilizou 25 raízes divididas em cinco grupos de cinco espécimes. Três espécimes de cada grupo foram inoculados com uma das culturas bacterianas e seus fagos correspondentes na proporção 1:1, por um período de três horas a 37 °C, enquanto os outros dois, receberam a cultura de microrganismos ou somente meio de cultura (controle positivo e negativo, respectivamente). No segundo experimento, 11 espécimes receberam um inóculo formado pelas cinco cepas por um período de 10 dias de incubação a 37 °C, com o propósito de manter condições apropriadas para a penetração das bactérias no interior dos túbulos dentinários, e um outro espécime recebeu apenas meio de cultura (controle negativo). Essa penetração foi confirmada empregando-se microscopia ótica e eletrônica realizada em dois espécimes. Após o período de incubação, o lisado polivalente, preparado com os cinco fagos, foi aplicado por 24 horas a 37 °C em 8 espécimes, e os demais preenchidos com meio de cultura (controle positivo e negativo). Alíquotas do interior de todos os canais foram colhidas antes e depois do contato com os fagos e no segundo experimento, também 24 e 48 horas depois, para semeadura e contagem de unidades formadoras de colônia. Os resultados do primeiro experimento mostraram 100% de redução do crescimento bacteriano nos espécimes que receberam a suspensão de fagos específicos, em comparação a seus respectivos controles positivos, em todos os grupos. No segundo experimento, foi comparado o crescimento obtido após os 10 dias de infecção com aquele posterior a aplicação dos fagos, redução que variou entre 50% e 100%. Diante desses resultados, conclui-se que os bacteriófagos foram eficazes na diminuição dos microrganismos presentes no interior de canais radiculares e nos túbulos dentinários de dentes humanos. / Many studies have investigated different intracanal medications to control infection processes, especially in cases of microbial resistance to disinfection procedures. The purpose of this study was to evaluate the in vitro antimicrobial effect of specific bacteriophages on five isolates of Enterococcus faecalis, as well as the activity of a lysate cocktail in eliminating the infection caused by these bacteria. Thirty-seven recently extracted human teeth of approximately equal size and with single roots were used. The crowns were removed and each canal was prepared using K files,up to # 45, and sterile physiological saline. Specimens were then sterilized and used in two separate studies. The first study utilized 25 individual roots divided into five groups of five specimens each. Three specimens of each group were inoculated with one of the bacterial cultures and the corresponding bacteriophage in a proportion of 1:1, and incubated for three hours at 37°C; the other two specimens were inoculated with only the bacterial culture or only the culture medium (positive and negative controls, respectively). In the second study, 11 specimens were inoculated with all five strains and incubated for ten days at 37°C in order to allow bacteria to penetrate the interior of the dental tubules, and another one, received just the culture medium (negative control). Penetration into the tubules was confirmed by optical and electron microscopy of two specimens. Following incubation, the lysate cocktail prepared using all five bacteriophages was applied to the other 8 specimens for 24 hours at 37°C, and 2 specimens were filled with the culture medium (positive and negative controls). In the first study, samples were taken from the lumen of all canals before and after contact with bacteriophages; in the second, aliquots were also taken 24 and 48 hours after the bacteria were exposed to the phages. All samples were diluted and plated and the number of colony forming units was counted. In the first study, there was a 100% reduction in bacterial growth in specimens that received the specific bacteriophage suspension compared to the positive controls within each group. In the second study, after ten days the number of bacteria was reduced by 50% to 100% following the bacteriophage application. These results suggest that bacteriophages are effective in reducing the number of bacteria inside the root canal and in the dental tubules of human teeth.

Ação antimicrobiana

Antimicrobial activity

Bacteriófago

Bacteriophage

Fagoterapia

Infecção persistente

Intracanal medication

Medicação intracanal

Persistent infection

Phage therapy