CRISPR-Cas9 modified bacteriophage for treatment of Staphylococcus aureus induced osteomyelitis and soft tissue infection
Authors:
Leah H. Cobb aff001; JooYoun Park aff002; Elizabeth A. Swanson aff003; Mary Catherine Beard aff001; Emily M. McCabe aff001; Anna S. Rourke aff001; Keun Seok Seo aff002; Alicia K. Olivier aff004; Lauren B. Priddy aff001
Authors place of work:
Department of Agricultural and Biological Engineering, Mississippi State University, Mississippi State, Mississippi, United States of America
aff001; Department of Basic Sciences, College of Veterinary Medicine, Mississippi State University, Mississippi State, Mississippi, United States of America
aff002; Department of Clinical Sciences, College of Veterinary Medicine, Mississippi State University, Mississippi State, Mississippi, United States of America
aff003; Department of Pathobiology and Population Medicine, College of Veterinary Medicine, Mississippi State University, Mississippi State, Mississippi, United States of America
aff004
Published in the journal:
PLoS ONE 14(11)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0220421
Summary
Osteomyelitis, or bone infection, is often induced by antibiotic resistant Staphylococcus aureus strains of bacteria. Although debridement and long-term administration of antibiotics are the gold standard for osteomyelitis treatment, the increase in prevalence of antibiotic resistant bacterial strains limits the ability of clinicians to effectively treat infection. Bacteriophages (phages), viruses that in a lytic state can effectively kill bacteria, have gained recent attention for their high specificity, abundance in nature, and minimal risk of host toxicity. Previously, we have shown that CRISPR-Cas9 genomic editing techniques could be utilized to expand temperate bacteriophage host range and enhance bactericidal activity through modification of the tail fiber protein. In a dermal infection study, these CRISPR-Cas9 phages reduced bacterial load relative to unmodified phage. Thus we hypothesized this temperate bacteriophage, equipped with the CRISPR-Cas9 bactericidal machinery, would be effective at mitigating infection from a biofilm forming S. aureus strain in vitro and in vivo. In vitro, qualitative fluorescent imaging demonstrated superiority of phage to conventional vancomycin and fosfomycin antibiotics against S. aureus biofilm. Quantitative antibiofilm effects increased over time, at least partially, for all fosfomycin, phage, and fosfomycin-phage (dual) therapeutics delivered via alginate hydrogel. We developed an in vivo rat model of osteomyelitis and soft tissue infection that was reproducible and challenging and enabled longitudinal monitoring of infection progression. Using this model, phage (with and without fosfomycin) delivered via alginate hydrogel were successful in reducing soft tissue infection but not bone infection, based on bacteriological, histological, and scanning electron microscopy analyses. Notably, the efficacy of phage at mitigating soft tissue infection was equal to that of high dose fosfomycin. Future research may utilize this model as a platform for evaluation of therapeutic type and dose, and alternate delivery vehicles for osteomyelitis mitigation.
Keywords:
Staphylococcus aureus – antibiotics – Bacteriophages – Bacterial biofilms – Gels – Osteomyelitis – Vancomycin – Soft tissue infections
Introduction
For nearly a century, antibiotics have been a vital resource utilized by clinicians to eliminate infection, with nearly 270 million prescriptions dispensed in 2015 alone[1]. Antibiotics are utilized for a variety of infections, from common otitis externa (“swimmers ear”) to severe endocarditis, pneumonia, meningitis or osteomyelitis. Although antibiotics are typically able to clear infection, antibiotic resistant strains of bacteria continue to emerge. It is not as lucrative, nor as feasible, for pharmaceutical companies to develop novel antibiotics at the rates that these multi-drug resistant (MDR) bacterial strains are isolated. Nationally, approximately $2.2 billion is spent annually to treat MDR bacterial infections[2]. By 2050, it is estimated that nearly 10 million people could die each year due to resistant strains of bacteria[3].
Staphylococcus aureus (S. aureus), a Gram-positive bacterial strain, is one of the most commonly isolated and arguably one of the most detrimental pathogens with antibiotic resistance. One of the most common antibiotic resistant strains of S. aureus is methicillin- resistant S. aureus (MRSA). MRSA alone was responsible for over 80,000 reported infections in 2011 alone, of which 11,285 resulted in death[4]. S. aureus is able to achieve antibiotic resistance with genomic changes such as altered synthesis of peptidoglycan, a major component of the bacterial cell wall. Additionally, some strains of S. aureus can produce biofilms, an extracellular polymeric matrix including dead bacterial cells, which surrounds and protects the living, underlying layer of S. aureus[5]. These biofilms can be difficult to penetrate, and oftentimes require surgical intervention to remove.
Difficulties in treating osteomyelitis, or the infection of bone, have been exacerbated by the rise of antibiotic resistant bacterial strains, particularly S. aureus strains, which are the most common cause of bone infection[6]. Of diabetic foot ulcers, which occur in 25% of diabetic patients, approximately 20% will spread to nearby bone tissues and result in osteomyelitis[7]. As diabetic diagnoses continue to increase in the United States with an expected 55 million to be afflicted by 2030, osteomyelitis infections will be an ongoing challenge for the healthcare community[8]. It is essential that new therapeutics be engineered and tested, for rapid translation into clinical use.
Bacteriophages (phages), or viruses that while in a lytic state kill their bacterial hosts, are one class of therapeutics that have gained attention in recent years due to their high specificity, non-toxicity, and abundancy in nature[9,10]. Phages have been used for decades in Eastern Europe but have not yet been adopted in the United States or other countries. This may be due to public concern regarding elective viral use, issues concerning commercial phage production, and/or the ability to fund and validate clinical trials[11]. Nonetheless, the potential benefits of this treatment have been indicated by results of clinical trials of phages for treating diabetic foot ulcers, chronic otitis, and urinary tract infections[11–13]. In April 2019, data from clinical trials were published from Sydney, Australia, where intravenous (IV) administration of phage was utilized for Staphylococcus infection treatment. Marked reduction of staphylococci with no adverse events were reported[14]. In the United States as of January 2019, IV administration of phage for ventricular assist device infection treatment received approval for phase I/II clinical trials[15]. Collectively, these clinical trials demonstrate the efficacy of bacteriophage therapeutics and suggest their potential utility against MDR bacterial strains.
Hydrogels are a commonly used, easily tailored delivery vehicle for therapeutics for a wide variety of ailments, including osteomyelitis[6,16,17]. Alginate hydrogels are injectable, well characterized, and biocompatible[18,19]. Furthermore, bacteriophages have been successfully delivered to sites of infection with various hydrogel-based delivery systems in previous studies[16,17,20].
Although the high specificity of phages can be beneficial for treating a known, single species, specificity of these viruses can make polymicrobial infection mitigation challenging. In the clinical scenario, it is ideal for health care providers to administer one broad-spectrum drug immediately upon patient presentation, rather than spend time identifying the causative agents of infection. Previously, we have generated CRISPR-Cas9 to modify temperate bacteriophage in the host strain in which all staphylococcal cytotoxin and enterotoxin genes were removed to prevent contamination of these toxins in the phage solution for increasing safety of phage therapy. In vitro testing revealed the improvements of bacteriophage bactericidal activity due to this CRISPR-Cas9 system[21]. Within 6h of treatment, the CRISPR-Cas9 phage effectively killed 1x105 CFU S. aureus culture. With native, unmodified phage treatment, the culture was found to increase to approximately 1x109 CFU. Similar effects were noted in an in vivo dermal infection study, where CRISPR-Cas9 phage treatment resulted in nearly complete mitigation of dermal infections (~1 log CFU/g tissue), while treatment with unmodified phage resulted in a significantly higher bacterial load (~3.5 log CFU/g tissue)[21].
The objectives of the present work were: (i) to develop a green fluorescent protein (GFP) integrated S. aureus strain (ATCC 6538-GFP), (ii) evaluate the bactericidal efficacy of our previously modified CRISPR-Cas9 bacteriophage in vitro, compared to conventional antibiotics, and (iii) to develop an in vivo model of osteomyelitis and soft tissue infection using this biofilm forming S. aureus strain, and use it to assess the antimicrobial effects of bacteriophage, antibiotic, and dual bacteriophage-antibiotic therapies via histological, radiographic, and bacteriological analyses. Our hypothesis was that CRISPR-Cas9 modified bacteriophage would be effective against S. aureus infection in vitro and in the femur and contiguous soft tissue in vivo.
Materials and methods
Bacterial strains and culture
For a stable quantification of biofilm, S. aureus strain ATCC 6538 was genetically modified to contain chromosomally integrated green fluorescent protein (GFP), as previously described[22]. Briefly, S. aureus strain ATCC 6538 was transformed with a temperature sensitive plasmid pTH100 harboring the GFP gene by electroporation and cultured in a brain heart infusion (BHI) agar plate supplemented with chloramphenicol (BHI-CM) at 30°C, a plasmid replication permissive temperature. To promote the first homologous recombination and cure pTH100, a single colony grown in a BHI-CM plate was transferred to a fresh BHI-CM plate and cultured at 42°C, a plasmid replication non-permissive temperature. To promote the second homologous recombination, which removed the plasmid and resulted in a loss of chloramphenicol resistance but maintained the GFP phenotype, a single colony was inoculated into BHI broth and cultured at 37°C overnight. A serial dilution of culture was inoculated onto a BHI plate and incubated at 37°C overnight. A GFP positive single colony checked by ultraviolet lamp was randomly selected and streaked onto BHI and BHI-CM. A colony that was both GFP positive and sensitive to chloramphenicol, indicating the integration of the GFP gene into the chromosome and removal of plasmid, was selected for experiments (ATCC 6538-GFP).
For longitudinal assessment of fluorescence in ATCC 6538-GFP, images were collected at days 1, 3, and 7 (IVIS Lumina XRMS II, PerkinElmer). Individual colonies (n = 5) at each timepoint were selected as regions of interest (ROIs), and the radiance (fluorescence) was quantified (IVIS Living Image software, v4).
Preparation of alginate hydrogels
All alginate gels were initially prepared at a 3% (w/v) concentration, for ultimate dilution to 2% after loading them with therapeutic. A 3% alginate mixture (w/v) was made with alginic acid powder (Sigma-Aldrich) and alpha Minimum Essential Medium (αMEM, Gibco) then left overnight at room temperature. This solution was sterile filtered (0.2 μm, Pall) and transferred into 1mL syringes. Therapeutics were then added directly to the alginate. The crosslinker, calcium sulfate (0.21g CaSO4 / mL distilled H2O) was loaded into a separate 1mL syringe and was mixed vigorously with the alginate solution for approximately one minute. Hydrogels were kept at 4°C or on ice until use.
Induction of CRISPR-Cas9 modified bacteriophages
S. aureus strain RF122 harboring CRISPR-Cas9 modified bacteriophage was cultured in BHI broth to the mid-exponential phase (OD600 at 0.3)[21]. The CRISPR-Cas9 modified bacteriophage was initially induced by adding mitomycin C (1 μg/mL, Sigma-Aldrich) which caused a complete lysis of culture typically within 2–3 hours. The CRISPR-Cas9 modified bacteriophage was further propagated by inoculating to the mid-exponential phase culture of S. aureus strain RF122. The clear lysate was sterilized with syringe filers (0.22 μm, Nalgene). To remove bacterial proteins and concentrate phage titer, clear lysates were filtered using Amicon centrifugal filter unit (100 kDa cut off, Sigma-Aldrich). The concentration of phage was calculated by determining the plaque-forming unit (pfu) using a soft agar (0.5%, w/v) overlaying method[21].
Kirby-Bauer analyses
To analyze the bactericidal activity of therapeutics, a Kirby-Bauer assay was performed as previously described, with slight modifications[23]. Stock solutions of fosfomycin (50 mg/mL) and phage (~1×108 pfu/mL) were prepared in phosphate buffered saline (PBS). Using these stock solutions, a total of 10μL of: (i) fosfomycin, (ii) phage, (iii) dual: fosfomycin (5μL) and phage (5 μL), or (iv) PBS alone (n = 6) were directly applied to bacterial lawns, without the use of disks as traditionally described. The applied solutions were allowed to set undisturbed for approximately 5–10 minutes at room temperature, and were then incubated at 37°C for 24h. The zones of inhibition were then measured and recorded.
Qualitative and quantitative bactericidal activity on biofilms
For qualitative in vitro evaluation of antibiofilm efficacy, a 6-well tissue culture plate was pre-coated with 2% human serum for 24 hours, after which Staphylococcus aureus ATCC 6538-GFP was cultured in tryptic soy broth (TSB) supplemented with 2% glucose for 72 hours. After gentle washing with PBS, TSB supplemented with vancomycin (256, 512, or 1024 μg/mL), fosfomycin (16, 64, 128 μg/mL) or bacteriophage (5×107, 1×108, 2.5×108 pfu/mL) was added to the biofilm and incubated for 24 hours. S. aureus cultured in TSB growth media alone served as the control. After gentle washing with PBS three times, remaining biofilm indicated by GFP signal was measured using Cytation 5 plate reader (BioTek).
The antibiofilm activity of selected therapeutics delivered by alginate hydrogels was quantified as previously described, with slight modifications[6]. A colony of ATCC 6538 was grown in BHI for 24h at 37°C, 150 RPM. Then, ~104 CFU of ATCC 6538 was added to 48-well tissue culture-treated plates containing 500 μL of 1% glucose BHI media. The biofilm was cultured statically for 24h at 37°C. All media was then carefully removed, and the biofilm was gently washed with 1mL PBS. Then, 100 μL of fosfomycin (3 mg), phage (3×107 pfu/mL), or dual (1.5 mg fosfoymcin, 1.5x107 pfu/mL phage) therapeutic loaded into 2% alginate hydrogels were placed on top of biofilms (n = 3)[6]. As a control, empty 2% alginate hydrogel and PBS were used (n = 3). 400 μL of 1% glucose BHI was added and cultures were incubated at 37°C up to 24h. After removing BHI broth, the entire 2% alginate hydrogel (or PBS) and biofilm were harvested and vigorously washed with PBS by centrifugation to remove residual therapeutic. A serial dilution in PBS was plated onto BHI plates to determine viable bacterial counts.
Rat osteomyelitis model
Animal research performed in this work was approved and monitored by the Institutional Animal Care and Use Committee (IACUC) of Mississippi State University under protocol 17–097. Buprenorphine was used for pain management, isofluorane was used as an anesthetic agent, and CO2 was used for euthanasia. See Fig 1 for an overview of in vivo procedures. Charles River Sprague Dawley female rats, 13 weeks old, were housed with 12h light/dark cycles and were provided food and water ad libitum. Rats were administered slow release buprenorphine (1.0–1.2 mg/kg BW, ZooPharm) pre-operatively for pain relief. Rats were anesthetized with isoflurane at an initial concentration of 2–3%, and maintained at 1–2%. After sterile preparation of the left hindlimb by fur removal and alcohol and chlorhexidine scrubs, the skin was incised with an anterior approach, from the level of mid-diaphysis to the patella, along the lower half of the femur. The muscle tissue was separated using blunt dissection along the muscle bundle divisions on the anterolateral side of the femur. In the mid-diaphysis, a 1.2 mm (diameter) bicortical defect was created with a pneumatic drill (Conmed Hall), and a #65 drill bit (McMaster-Carr). To mimic contamination of orthopedic screws with S. aureus occurring in development of osteomyelitis in vivo, sterile orthopedic screws (Antrin Miniature Specialties, #00–90) were placed into 200 μL of a bacterial suspension (~1x108 CFU) of ATCC 6538-GFP for approximately 5–10 minutes (average 6.5 min). The screw was then placed into a 96-well plate to dry for up to 6 minutes (average 4 min). The bacterial load of these contaminated screws was approximately 5x104 CFU, determined by placing screws into 1mL of PBS, vigorously vortexing to elute bacteria from the screw, then serially diluting the eluents for bacterial counting on BHI agar plates. In vitro characterization of bacterial load based on (i) the time screws remained in culture (soak time) and (ii) dry time was performed using the same procedure as for bacterial counts from ex vivo screws. To assess the effect of soak time, dry time was kept at a constant 5 minutes, and similarly for the effect of dry time, soak time was kept constant at 5 minutes. To complete the in vivo procedure, the superficial fascia lata and skin were closed with sutures. Longitudinal monitoring of infection at days 1, 3, and 6 post-infection was performed via radiographs with fluorescent overlays using the IVIS Lumina XRMS II system.
After a 7-day infection period, the area was accessed along the original incision line. The infected screw was removed and placed into 1mL PBS or fixative for bacterial counting or SEM, respectively. Then, 100 μL of fosfomycin (3 mg), phage (3×107 pfu/mL), dual (3 mg fosfomycin and 3×107 pfu/mL phage), or PBS loaded into 2% alginate hydrogel was injected into the lateral end of the bicortical defect, with excess hydrogel pooling in the medial, underlying soft tissue.
On day 8, approximately 24 hours post-treatment, animals were sacrificed via CO2 inhalation. The hindlimb was initially cleaned with chlorhexidine, and sterile instruments were used to disarticulate the femur and adjacent soft tissues for further evaluation. For bacterial counting, bone samples (n = 9) were initially minced using sterile bone rongeurs and further processed using a homogenizer (Cole-Parmer, LabGEN7, 30s at setting 2–3, 30s at setting 9–10). Soft tissue samples (n = 10) were minced using sterile surgical scissors, then homogenized (30s at setting 2–3, 30s at setting 7–8). Following initial processing, homogenates were vortexed (2000 RPM, 1 minute), diluted as necessary, spread onto BHI agar plates, and incubated for 24 hours at 37°C for enumeration, with a detection limit set at 25–250 colonies.
Electron microscopy and histological analyses
Screw samples for electron microscopy analysis were collected during revision surgeries on day 7 immediately prior to application of treatment, and placed directly into a fixative consisting of 5% glutaraldehyde, 2% paraformaldehyde (w/w) in a sodium cacodylate buffer (a modified “Karnovsky’s” solution)[24]. For electron microscopy analysis of infected bone, a representative control femur (empty alginate group) was collected at day 8, broken along the screw line with sterile bone rongeurs, and immediately placed in fixative for 24h. For both the screw and bone samples, no dehydration series was performed in order to preserve the biofilm. Prior to imaging, both samples were placed onto stubs with carbon tape and sputter coated (Quorom Tech Model # SC7640) with platinum at 30 mA and 3.5 kV for 3–5 minutes. All samples were then imaged using FESEM (Carl Zeiss AG-SUPRA 40).
For histological analyses, the infected femur and adjacent soft tissues were placed into 10% formalin for 48h, at ~20°C. Bone samples were decalcified for 5 days in Kristensen’s solution, then rinsed and placed into 10% formalin[25]. Tissues were routinely processed, embedded in paraffin, sectioned at 5μm, and Gram or hematoxylin and eosin (H&E) stained.
Statistical analyses
All statistical analyses were performed using either GraphPad Prism 8 or SAS software systems. For the longitudinal fluorescence measurements and Kirby-Bauer assay, one-way analysis of variance (ANOVA) with Tukey’s multiple comparisons test were performed. For the in vitro antibiofilm assay, a two-way ANOVA with Tukey’s multiple comparisons were performed. For bacterial counts from directly prepared and ex vivo orthopedic screws, a one-way ANOVA was performed, with Sidak’s multiple comparisons. All aforementioned statistical analyses were performed using GraphPad Prism 8 (GraphPad Software, Inc.). For bone and soft tissue ex vivo bacterial counts, general linear models using PROC MIXED in SAS (SAS Institute, Inc.) were performed, with pairwise comparisons using Tukey’s (comparing treatment groups to one another) or Dunnett’s (comparing each treatment to control) tests. An alpha level of 0.05 was used to determine statistical significance for all methods. Data are presented as mean ± standard deviation (SD).
Results
Integration of GFP into S. aureus
Longitudinal analyses of infection progression and regression is an ideal tool for new model generation. Plasmids harboring reporter genes such as luminescence and fluorescence have been most commonly used; however, it is necessary to constantly provide antibiotic selective pressure to prevent a loss of plasmid, which is not achievable with in vivo models. In this study, we integrated the GFP reporter gene into the genome of S. aureus ATCC 6538 strain for the stable and accurate assessment of bacterial growth. Although the magnitude of S. aureus grown onto BHI agar plates (without antibiotic selective pressure) varied slightly over time, individual S. aureus ATCC 6538-GFP colonies exhibited consistent expression of GFP over a span of 7 days (Fig 2A). Furthermore, ATCC 6538-GFP recovered from an ex vivo orthopedic screw at day 7 post-infection demonstrated GFP expression was maintained (Fig 2B). These results demonstrated that S. aureus ATCC 6538 chromosomally integrated with GFP can be used for real-time monitoring of bacterial proliferation in vitro and in vivo.
Kirby-Bauer analyses revealed efficacy of fosfomycin, phage, and dual therapeutics on static S. aureus culture
From the Kirby-Bauer assay, all therapeutics delivered via PBS had a greater antibacterial effect than the PBS control (p<0.0001), which generated no zone of inhibition (“N.D.”). Dual and fosfomycin therapeutics also generated a zone of inhibition greater than phage treatment (p<0.0001).
Fosfomycin and phage exhibited bactericidal activity on biofilms in both qualitative and quantitative in vitro assays
Biofilms are generally considered the greatest agent of osteomyelitis treatment failure, and thus are important to consider when developing therapeutics. For this reason, it is important to evaluate the efficacy of novel therapeutics on robust biofilms, for translation into relevant clinical scenarios. Antibiofilm efficacy of therapeutics in vitro was characterized utilizing two different analyses: (i) qualitative fluorescent (phenotypic) assessment and (ii) quantitative bacterial counting. Vancomycin (256–1024 μg/mL), fosfomycin, (16–128 μg/mL) and bacteriophage (5×107, 1×108, 2.5×108 pfu/mL) delivered via PBS revealed varied bactericidal activity (Fig 3B). Interestingly, vancomycin appeared to have little to no efficacy on biofilm at any concentration. Fosfomycin, in contrast, showed efficacy at 64 and 128 μg/mL, a dose range approximately one-tenth the vancomycin doses utilized. Bacteriophage was effective at the doses of 1×108 and 2.5×108 pfu/mL, indicated by the black panel revealing no viable S. aureus.
Alginate is a versatile biopolymer used for prolonged, localized availability of therapeutic [26]. Antibiofilm assays with bacterial counts were utilized to quantitatively assess the effects of selected therapeutics over time delivered via alginate (Fig 3C). In all treatment groups where alginate was loaded with therapeutic(s), antibiofilm effects increased over time. Fosfomycin-treated biofilms resulted in an average load of 10.388, 9.803, and 8.241 log10 (CFU) at 6, 12, and 24h timepoints, respectively, with differences observed between 6 and 12 hours, and 12 and 24 hours (p<0.0001). Phage-treated wells resulted in an average of 10.480, 9.825, and 9.762 log10 (CFU) at 6, 12, and 24h, respectively, with differences seen between 6 and 12 hours, and 6 and 24 hours (p<0.05). Dually-treated biofilm groups differed when comparing the 6 v. 12h, 6 v. 24h, and 12 v. 24h timepoints (p<0.0001), with average bacterial loads of 10.816, 9.801, and 8.712 log10 (CFU) at 6, 12, and 24h, respectively. As expected, the empty alginate and PBS controls did not change over time.
Compared to the empty alginate group, alginate-loaded fosfomycin, phage, and dual therapeutic-treated biofilms had lower bacterial loads at 6, 12, and 24 hours (except the fosfomycin group at 6 hours) (p<0.05). All groups (fosfomycin, phage, dual, and empty alginate gel) had lower growth at all time points compared to the PBS control, i.e., the empty alginate gel exerted a killing effect (p<0.05).
Quantification of bacterial load on orthopedic screws before and after in vivo infection
To generate consistent infection in the osteomyelitis model, contaminated orthopedic screw preparation had to first be characterized. Two parameters of screw preparation were evaluated: soak time and dry time. Soak time (5–20 min) of screws appeared to increase somewhat proportionally with respect to bacterial load (Fig 4A). Dry times from 0–10 min appeared to have little effect on bacterial load; at 20 min, decreased viability of S. aureus was observed (Fig 4B).
In the in vivo model, orthopedic screws removed at day 7 to allow injection of therapeutic into the infected defect space were analyzed for bacterial load to confirm all treatment groups began with a similar extent of infection. Bacterial counts from ex vivo screws indicated similarly severe infection among all samples (treated immediately following), with an average 8.19x104 CFU/mL bacterial load (Fig 4C). Per what would become individual treatment groups, calculated averages were: 1.1x105, 7.5x104, 8.2x104, and 6.6x104 for fosfomycin, phage, dual, and control groups, respectively. No significant differences between any groups were observed.
Scanning electron microscopy revealed an abundance of S. aureus on excised orthopedic screws and bone fragments
Representative SEM images of screws collected at day 7 post-infection revealed an abundance of Gram-positive cocci (S. aureus), as expected, along the distal portion of the screw and within the ridges of the screw throughout its length (Fig 5A and 5B). In bone fragments collected along the screw line (defect site) of an untreated (empty alginate) control sample at day 8 (24h post-treatment), Gram positive cocci, presumably S. aureus, were visible. (Fig 5C and 5D).
Bacterial loads of excised bone and soft tissues revealed limited efficacy of phage therapeutics in bone but significant reduction in soft tissue from all therapeutics
The average bone bacterial counts per treatment group were as follows: (i) control: 4.197 ± 0.289, (ii) fosfomycin: 3.401 ± 0.924, (iii) phage: 4.076 ± 0.268, and (iv) dual: 3.607 ± 0.316 (Log10(CFU)), Fig 6A). Fosfomycin bacterial counts were lower than empty alginate control (p = 0.0083) and phage (p = 0.0486).
The average soft tissue bacterial counts per treatment group were as follows: (i) control: 4.713 ± 0.331, (ii) fosfomycin: 4.146 ± 0.377, (iii) phage: 4.160 ± 0.516, and (iv) dual: 4.201 ± 0.556 (Log10(CFU)), Fig 6B). Bacterial counts were lower in fosfomycin (p = 0.0225), phage (0.0265), and dual (p = 0.0430) treated groups compared to empty alginate control.
Histological analyses of infected femurs demonstrated hallmarks of osteomyelitis infection
Bone samples stained with H&E or Gram revealed strong evidence for development of a severe osteomyelitis infection. The areas at the site of the screw were characterized by extensive remodeling within the medullary cavity, with replacement of marrow cells by a central area of neutrophils surrounded by fibrovascular proliferation and reactive bone. Within the cortex, at the site of screw placement, was mild bone necrosis characterized by empty lacunae and bone loss. Along the periosteal surface there was locally extensive proliferation of woven bone (periosteal proliferation). Additionally, abundant Gram-positive cocci were localized within the bone. No differences in the extent of infection among any groups were apparent. The outcome of the fosfomycin-treated bone histology varied from the other samples, due to sample damage during processing. Ultimately, this prevented the collection of images along the screw line (where the majority of bacteria and inflammation were localized), as seen with the other groups. However, the proliferation of woven bone, as a reactive process on the cortical surface, is visible (Fig 7B). Within the phage-treated bone sample, a linear track of Gram-positive bacteria in the bone at the original site of the screw line was visible (Fig 7C). In the dual-treated sample, neutrophilic inflammation surrounded by reactive bone and fibrosis was observed (Fig 7D left, *).
Discussion
In this manuscript, a previously developed CRISPR-Cas9 modified bacteriophage therapeutic, which was successful in treating external dermal infection[21], was evaluated as a therapeutic for internal osteomyelitis and contiguous soft tissue infection in a rat model using a biofilm forming strain of S. aureus. For real time monitoring of S. aureus, GFP was chromosomally integrated into S. aureus ATCC 6538 strain by homologous recombination. We demonstrated that S. aureus ATCC 6538 strain carrying the GFP gene stably maintained the GFP phenotype without antibiotic selective pressure in vitro and in vivo.
The therapeutic effects of vancomycin, fosfomycin, CRISPR-Cas9 modified bacteriophage, and fosfomycin-bacteriophage dual treatments were evaluated against biofilm in vitro. Surprisingly, vancomycin, one of the most commonly utilized “last resort” antibiotics for difficult osteomyelitis cases, appeared to have little or no effect on biofilm. Recent guidelines recommend vancomycin trough concentrations between 15 and 20 μg/mL for effectively controlling S. aureus infection[27]. As biofilms are typically more difficult to treat than planktonic bacteria, a much higher concentration of vancomycin (256–1024 μg/mL) was used here. In the absence of vancomycin resistance genes, many S. aureus strains were sensitive to vancomycin less than 8 μg/mL in BHI broth[28]. However, once it formed a biofilm, S. aureus ATCC 6538-GFP was highly resistant to vancomycin even at 1024 μg/mL. Biofilms consist of a group of bacteria and their byproducts such as extracellular polymeric substances (EPS) including proteins, DNA, RNA, polysaccharides, and peptidoglycans. These EPS materials provide physical barriers to penetration of antibiotics to the inner viable population of bacteria in the biofilm. Vancomycin, a large glycopeptide antibiotic with a molecular weight of 1,449 g/mol, binds to the D-ala-D-ala terminal amino acid at the stem of pentapeptide crosslinking peptidoglycan for efficacy[29]. Thus, resistance to vancomycin by biofilm may be explained by poor penetration of vancomycin due to its bulky size, which could have led to entrapment at the peptidoglycan layer of biofilm. In contrast, fosfomycin showed better efficacy against biofilm at much lower (64 and 128 μg/mL) doses. This enhanced effect of fosfomycin over vancomycin has been reported in vitro and in vivo by others[30,31]. Fosfomycin is a small (138 g/mol) broad-spectrum antibiotic and promising therapeutic option against biofilm[32]. It interferes with the first step of peptidoglycan synthesis by inhibiting the phosphoenolpyruvate synthetase[33]. Thus, the enhanced fosfomycin efficacy could be explained by better penetration of fosfomycin due to its small size and its inhibition of the first step of peptidoglycan synthesis. From qualitative fluorescent analyses, it was determined that phage at the concentration of 1×108 pfu/mL was effective in clearing biofilm in vitro. This is similar and in some cases an improvement upon in vitro efficacy of phage treatments discussed in literature, with biofilm eradication reported with MOI 10–100[21,34,35]. The CRISPR-Cas9 modified bacteriophage has dual killing mechanisms: (i) a direct lysis of target bacteria by holin or murein hydrolase, and (ii) CRISPR-Cas9 nuclease activity[21]. Furthermore, the antimicrobial effects of phage observed here are believed to be a result of the phage itself, rather than any bactericidal substances in the lysates used to generate the phage, since we have previously demonstrated that lysates from phages without the CRISPR/Cas9 system did not show any bactericidal effect[21]. Alginate hydrogel served as an effective delivery vehicle, enabling increasing effects against biofilm over a 24h period, for fosfomycin, phage, and dual treatments in vitro. Previously, we have observed similar sustained effects of bone morphogenetic protein-2 released from and retained within alginate hydrogels in vitro and in vivo[18,26].
For further evaluation of the CRISPR-Cas9 phage, motivated by augmented in vitro efficacy relative to antibiotic controls, we developed a clinically relevant model of implant-related osteomyelitis. In human cases of osteomyelitis, chronic infection is diagnosed after a 6-week period of infection, while our model had only a 1-week infection period. Based on SEM images, 1 week appeared to be sufficient to induce severe infection, including biofilm, in this rat model. By culturing S. aureus on orthopedic screws, infection was localized to the femur and surrounding soft tissue, as indicated by fluorescent imaging and histology. Fluorescent imaging served as a qualitative tool for longitudinal infection progression/regression, although no direct correlation between in vivo radiance output and ex vivo bone bacterial load was observed (https://doi.org/10.6084/m9.figshare.9941915.v1). This could be attributed at least in part to a residual GFP signal that likely exists after bacterial cell death (due to persistence of GFP), attenuation of signal in deep tissues such as the mid-diaphysis of the femur, and/or autofluorescence of probes <600 nm such as GFP[36]. Clinically, debridement accompanied by long-term antibiotic administration is the gold standard for osteomyelitis treatment[37]. In this study, we have avoided debridement altogether so as to limit potential clearing of infection from any source other than the therapeutics delivered. For future studies, debridement may be included to more readily mimic the clinical scenario and enable evaluation of larger antibacterial materials such as scaffolds or putties.
From bacterial counts performed on excised soft tissues, it was determined that severe soft tissue infection accompanied the expected high bacterial load in the bone samples. In clinical cases of osteomyelitis, soft tissue infection is a common pathological finding of osteomyelitis infection progression[38–40]. In this model, soft tissue infection likely developed due to the distal end of the orthopedic screw resting freely within the soft tissue medial to the defect site. On excised orthopedic screws collected on day 7, scanning electron microscopy indicated a purulent, thick biofilm layer of Staphylococci on the end of the orthopedic screw. Based on in vitro results, the process of contaminated orthopedic screw preparation can be used to tailor the extent of infection, as soaking the screws for a shorter period of time would be expected to introduce less S. aureus into the bone and as a result induce a less severe infection. Histology results support the development of severe osteomyelitis infection, with disease hallmarks such as neutrophilic inflammation, reactive bone, fibrosis, and Gram-positive bacteria. Within the 24-hour time frame of this study, no differences among treatment groups were apparent. If later time points were evaluated, the differences noted in bacterial counting would likely be more readily reflected histologically.
Although only the fosfomycin group resulted in reduced bacterial load in the femur, in soft tissue, all three treatments, including phage alone and phage with fosfomycin (dual) led to lower bacterial counts compared to empty alginate. It should be noted than an extremely high dose of fosfomycin (3g) was administered to the rat femur in this study. In humans, a 3g oral dose is recommended for treatment of urinary tract infections[32]. Conversely for bacteriophage dose, although a minimum effective dose of 1×108 pfu/mL was observed in vitro, in vivo only 3×107 pfu/ml of phage was able to be delivered due to: (i) the volume of alginate hydrogel delivered to the small defect site (100 μL total, but only ~10 μL fit into the defect itself), and (ii) the thicker consistency of phage solution, limiting the concentration that could be prepared in alginate hydrogel. Collectively, these discrepancies in dosing likely limited the efficacy of phage treatment alone in osteomyelitis mitigation relative to antibiotic with and without phage. Furthermore, the canaliculi of cortical bone may provide an ideal environment for bacteria to evade treatment[41]. It should also be noted that in this study, a one-time 100 μL treatment was applied locally. Clinically, osteomyelitis is treated via debridement and systemic antibiotics for several weeks[37]. Similarly, success with bacteriophage therapy has been associated with continuous, prolonged delivery of the virus. A bacteriophage cocktail was used to successfully clear femoral infection with four intraperitoneal doses of phage (100 μL of ~2x1012 pfu/mL) over the span of 48 hours[42]. Another study adopted a treatment regimen for tibial osteomyelitis consisting of a once daily 3x108 pfu/mL intramuscular bacteriophage injection for 14 days, which resolved the infection[43]. Recently, a case report was published describing the success of a weekly injection of bacteriophage over a seven-week period for human digital osteomyelitis[40]. Collectively, these data suggest that sustained, localized concentrations of phage may be necessary for efficacy in treatment of bone infection. In future studies, a greater initial dose of phage therapeutic may be delivered by concentration of phage via ultracentrifugation or polyethylene glycol precipitation, or a longer duration of treatment achieved with a delivery vehicle such as micro/nanoparticles capable of tailored release of therapeutic. Given a higher phage dose and/or prolonged availability, it is possible that the efficacy of phage observed here in vitro could be matched in vivo. Furthermore, it may be more advantageous to use alternating doses of the antibiotic and phage therapeutic over time, rather than a combined simultaneous application[44,45]. In this study, no additive effect of fosfomycin or phage was observed in the dual treatment group. Only a 24h treatment period was evaluated, which may have limited the effect of our selected therapeutics, as later time points may have allowed therapeutics, especially those containing phages (which must replicate for optimal bactericidal activity), to have a cumulative effect. Nonetheless, our challenging composite tissue infection model enabled efficient, rapid testing of antimicrobial therapeutics using a biofilm forming strain of S. aureus.
Despite the prevalence and severity of osteomyelitis, no bacteriophage-based treatment for the disease has reached clinical trials in the United States. As populations of MDR-bacteria continue to spread and new strains are isolated, engineering novel therapeutics will be essential to augment the dwindling list of effective, available antibiotics. Phage therapy has great potential to fill this niche, as phages can be made readily and at a low cost. Using CRISPR-Cas9 technology as in this study, phages can be modified to have a wide host range[21]. By contributing to the pipeline of bacteriophage therapeutic evaluation compared to traditional antibiotics, the goal of this work was to demonstrate efficacy of phage against bone and soft tissue infection. Enhanced bactericidal activity of CRISPR-Cas9 phage was demonstrated in vitro against biofilm, when compared to conventionally used vancomycin and fosfomycin antibiotics. Subsequently, an implant-related model of osteomyelitis and soft tissue infection was established, confirmed with histological, radiographic, and scanning electron microscopy analyses. Although phage did not mitigate bone infection 24h post-treatment, soft tissue infection was reduced 24h following treatment with bacteriophage, and notably to the same extent as treatment with high dose antibiotic. To improve bacteriological outcomes in the future, further investigations of delivery vehicles and optimal dosing are warranted.
Zdroje
1. Center for Disease Control and Prevention. Antibiotic Use in the United States, 2017: Progress and Opportunities. US Dep Heal Hum Serv. 2017.
2. Thorpe KE, Joski P, Johnston KJ. Antibiotic-Resistant Infection Treatment Costs Have Doubled Since 2002, Now Exceeding $2 Billion Annually. Health Aff (Millwood). United States; 2018;37: 662–669. doi: 10.1377/hlthaff.2017.1153 29561692
3. O’Neill J. Antimicrobial Resistance: Tackling a crisis for the health and wealth of nations. Rev Antimicrob Resist. 2014;
4. Tom Frieden. Antibiotic Resistance Threats. Cdc. 2013; CS239559-B
5. Archer NK, Mazaitis MJ, William Costerton J, Leid JG, Powers ME, Shirtliff ME. Staphylococcus aureus biofilms: Properties, regulation and roles in human disease. Virulence. 2011. doi: 10.4161/viru.2.5.17724 21921685
6. Johnson CT, Wroe JA, Agarwal R, Martin KE, Guldberg RE, Donlan RM, et al. Hydrogel delivery of lysostaphin eliminates orthopedic implant infection by Staphylococcus aureus and supports fracture healing. Proc Natl Acad Sci. 2018; doi: 10.1073/pnas.1801013115 29760099
7. Geraghty T, LaPorta G. Current health and economic burden of chronic diabetic osteomyelitis. Expert Review of Pharmacoeconomics and Outcomes Research. 2019. doi: 10.1080/14737167.2019.1567337 30625012
8. Rowley WR, Bezold C, Arikan Y, Byrne E, Krohe S. Diabetes 2030: Insights from Yesterday, Today, and Future Trends. Popul Health Manag. 2017; doi: 10.1089/pop.2015.0181 27124621
9. Abatángelo V, Peressutti Bacci N, Boncompain CA, Amadio AA, Carrasco S, Suárez CA, et al. Broad-range lytic bacteriophages that kill Staphylococcus aureus local field strains. PLoS One. 2017; doi: 10.1371/journal.pone.0181671 28742812
10. Tang Z, Huang X, Sabour PM, Chambers JR, Wang Q. Preparation and characterization of dry powder bacteriophage K for intestinal delivery through oral administration. LWT—Food Sci Technol. 2015; doi: 10.1016/j.lwt.2014.08.012
11. Furfaro LL, Payne MS, Chang BJ. Bacteriophage Therapy: Clinical Trials and Regulatory Hurdles. Front Cell Infect Microbiol. 2018; doi: 10.3389/fcimb.2018.00376 30406049
12. Wright A, Hawkins CH, Änggård EE, Harper DR. A controlled clinical trial of a therapeutic bacteriophage preparation in chronic otitis due to antibiotic-resistant Pseudomonas aeruginosa; a preliminary report of efficacy. Clin Otolaryngol. Wiley/Blackwell (10.1111); 2009;34: 349–357. doi: 10.1111/j.1749-4486.2009.01973.x 19673983
13. Leitner L, Sybesma W, Chanishvili N, Goderdzishvili M, Chkhotua A, Ujmajuridze A, et al. Bacteriophages for treating urinary tract infections in patients undergoing transurethral resection of the prostate: A randomized, placebo-controlled, double-blind clinical trial. BMC Urol. 2017; doi: 10.1186/s12894-017-0283-6 28950849
14. Fabijan AP, Lin RCY, Ho J, Maddocks S, Iredell JR. Safety and Tolerability of Bacteriophage Therapy in Severe Staphylococcus aureus Infection. bioRxiv. 2019; 619999. doi: 10.1101/619999
15. Voelker R. FDA Approves Bacteriophage TrialFDA Approves Bacteriophage TrialNews From the Food and Drug Administration. JAMA. 2019;321: 638. doi: 10.1001/jama.2019.0510 30778586
16. Johnson C, Dinjaski N, Prieto M, García A. Bacteriophage Encapsulation in Poly(Ethylene Glycol) Hydrogels Significantly Reduces Bacteria Numbers in an Implant-Associated Infection Model of Bone Repair. Igarss 2014.
17. Bean JE, Alves DR, Laabei M, Esteban PP, Thet NT, Enright MC, et al. Triggered Release of Bacteriophage K from Agarose/Hyaluronan Hydrogel Matrixes by Staphylococcus aureus Virulence Factors [Internet]. CHEMISTRY OF MATERIALS. pp. 7201–7208. doi: 10.1021/cm503974g
18. Priddy LB, Chaudhuri O, Stevens HY, Krishnan L, Uhrig BA, Willett NJ, et al. Oxidized alginate hydrogels for bone morphogenetic protein-2 delivery in long bone defects. Acta Biomater. 2014/06/17. 2014;10: 4390–4399. doi: 10.1016/j.actbio.2014.06.015 24954001
19. Krishnan L, Priddy LB, Esancy C, Li MTA, Stevens HY, Jiang X, et al. Hydrogel-based Delivery of rhBMP-2 Improves Healing of Large Bone Defects Compared With Autograft. Clin Orthop Relat Res. 2015; doi: 10.1007/s11999-015-4312-z 25917422
20. Souza GR, Yonel-Gumruk E, Fan D, Easley J, Rangel R, Guzman-Rojas L, et al. Bottom-up assembly of hydrogels from bacteriophage and Au nanoparticles: The effect of Cis- and trans-acting factors. PLoS One. 2008; doi: 10.1371/journal.pone.0002242 18493583
21. Park JY, Moon BY, Park JW, Thornton JA, Park YH, Seo KS. Genetic engineering of a temperate phage-based delivery system for CRISPR/Cas9 antimicrobials against Staphylococcus aureus. Sci Rep. 2017;7: 44929. Available: http://dx.doi.org/10.1038/srep44929
22. De Jong NWM, Van Der Horst T, Van Strijp JAG, Nijland R. Fluorescent reporters for markerless genomic integration in Staphylococcus aureus. Sci Rep. 2017; doi: 10.1038/srep43889 28266573
23. Bauer AW, Kirby WM, Sherris JC, Turck M. Antibiotic susceptibility testing by a standardized single disk method. Am J Clin Pathol. England; 1966;45: 493–496.
24. Karnovsky MJ. A Formaldehyde-Glutaraldehyde Fixative of High Osmolality for Use in Electron Microscopy. The American Society for Cell Biology Source: The Journal of Cell Biology. 1965.
25. Kristensen HK. An Improved Method of Decalcification. Stain Technol. Taylor & Francis; 1948;23: 151–154. doi: 10.3109/10520294809106242 18867628
26. Krishnan L, Priddy LB, Esancy C, Klosterhoff BS, Stevens HY, Tran L, et al. Delivery vehicle effects on bone regeneration and heterotopic ossification induced by high dose BMP-2. Acta Biomater. 2017; doi: 10.1016/j.actbio.2016.12.012 27940197
27. Lodise TP, Lomaestro B, Graves J, Drusano GL. Larger vancomycin doses (at least four grams per day) are associated with an increased incidence of nephrotoxicity. Antimicrob Agents Chemother. 2008; doi: 10.1128/AAC.01602-07 18227177
28. Weinstein RA, Fridkin SK. Vancomycin-Intermediate and -Resistant Staphylococcus aureus: What the Infectious Disease Specialist Needs to Know. Clin Infect Dis. 2001;32: 108–115. doi: 10.1086/317542 11118389
29. Wang F, Zhou H, Olademehin OP, Kim SJ, Tao P. Insights into key interactions between vancomycin and bacterial cell wall structures. ACS Omega. 2018; doi: 10.1021/acsomega.7b01483 29399648
30. Trautmann M, Meincke C, Vogt K, Ruhnke M, Lajous-Petter AM. Intracellular bactericidal activity of fosfomycin against staphylococci: A comparison with other antibiotics. Infection. 1992; doi: 10.1007/BF01710683 1293056
31. Poeppl W, Lingscheid T, Bernitzky D, Schwarze UY, Donath O, Perkmann T, et al. Efficacy of fosfomycin compared to vancomycin in treatment of implant-associated chronic methicillin-resistant Staphylococcus aureus osteomyelitis in rats. Antimicrob Agents Chemother. 2014; doi: 10.1128/AAC.02720-13 24936591
32. Dijkmans AC, Zacarías NVO, Burggraaf J, Mouton JW, Wilms E, van Nieuwkoop C, et al. Fosfomycin: Pharmacological, Clinical and Future Perspectives. Antibiotics. 2017; doi: 10.3390/antibiotics6040024 29088073
33. Takahata S, Ida T, Hiraishi T, Sakakibara S, Maebashi K, Terada S, et al. Molecular mechanisms of fosfomycin resistance in clinical isolates of Escherichia coli. Int J Antimicrob Agents. 2010; doi: 10.1016/j.ijantimicag.2009.11.011 20071153
34. Alves DR, Gaudion A, Bean JE, Perez Esteban P, Arnot TC, Harper DR, et al. Combined Use of Bacteriophage K and a Novel Bacteriophage To Reduce Staphylococcus aureus Biofilm Formation. Appl Environ Microbiol. 2014; doi: 10.1128/aem.01789-14 25149517
35. Pincus NB, Reckhow JD, Saleem D, Jammeh ML, Datta SK, Myles IA. Strain specific phage treatment for Staphylococcus aureus infection is influenced by host immunity and site of infection. PLoS One. 2015; doi: 10.1371/journal.pone.0124280 25909449
36. Koo V, Hamilton PW, Williamson K. Non-invasive in vivo imaging in small animal research. Cellular Oncology. 2006.
37. Nelson CL, McLaren SG, Skinner RA, Smeltzer MS, Thomas JR, Olsen KM. The treatment of experimental osteomyelitis by surgical debridement and the implantation of calcium sulfate tobramycin pellets. J Orthop Res. 2002; doi: 10.1016/S0736-0266(01)00133-4
38. Taki H, Krkovic M, Moore E, Abood A, Norrish A. Chronic long bone osteomyelitis: diagnosis, management and current trends. Br J Hosp Med. 2016; doi: 10.12968/hmed.2016.77.10.c161 27723401
39. Berbari EF, Kanj SS, Kowalski TJ, Darouiche RO, Widmer AF, Schmitt SK, et al. 2015 Infectious Diseases Society of America (IDSA) Clinical Practice Guidelines for the Diagnosis and Treatment of Native Vertebral Osteomyelitis in Adultsa. Clinical Infectious Diseases. 2015. doi: 10.1093/cid/civ633 26316526
40. Fish R, Kutter E, Bryan D, Wheat G, Kuhl S. Resolving Digital Staphylococcal Osteomyelitis Using Bacteriophage—A Case Report. Antibiotics. 2018; doi: 10.3390/antibiotics7040087 30279396
41. de Mesy Bentley KL, Trombetta R, Nishitani K, Bello-Irizarry SN, Ninomiya M, Zhang L, et al. Evidence of Staphylococcus Aureus Deformation, Proliferation, and Migration in Canaliculi of Live Cortical Bone in Murine Models of Osteomyelitis. J Bone Miner Res. 2017; doi: 10.1002/jbmr.3055 27933662
42. Kishor C, Mishra RR, Saraf SK, Kumar M, Srivastav AK, Nath G. Phage therapy of staphylococcal chronic osteomyelitis in experimental animal model. Indian J Med Res. 2016; doi: 10.4103/0971-5916.178615 26997019
43. Ibrahim OMS, Sarhan SR, Salih SI. Activity of Isolated Staphylococcal Bacteriophage in Treatment of Experimentally Induced Chronic Osteomyelitis in Rabbits. Adv Anim Vet Sci. 2016; doi: 10.14737/journal.aavs/2016/4.11.593.603
44. Lopes A, Pereira C, Almeida A. Sequential Combined Effect of Phages and Antibiotics on the Inactivation of Escherichia coli. Microorganisms. MDPI; 2018;6: 125. doi: 10.3390/microorganisms6040125 30563133
45. Tagliaferri TL, Jansen M, Horz H-P. Fighting Pathogenic Bacteria on Two Fronts: Phages and Antibiotics as Combined Strategy [Internet]. Frontiers in Cellular and Infection Microbiology. 2019. p. 22. Available: https://www.frontiersin.org/article/10.3389/fcimb.2019.00022 30834237
Článok vyšiel v časopise
PLOS One
2019 Číslo 11
- Metamizol jako analgetikum první volby: kdy, pro koho, jak a proč?
- Nejasný stín na plicích – kazuistika
- Masturbační chování žen v ČR − dotazníková studie
- Úspěšná resuscitativní thorakotomie v přednemocniční neodkladné péči
- Dlouhodobá recidiva a komplikace spojené s elektivní operací břišní kýly
Najčítanejšie v tomto čísle
- A daily diary study on maladaptive daydreaming, mind wandering, and sleep disturbances: Examining within-person and between-persons relations
- A 3’ UTR SNP rs885863, a cis-eQTL for the circadian gene VIPR2 and lincRNA 689, is associated with opioid addiction
- A substitution mutation in a conserved domain of mammalian acetate-dependent acetyl CoA synthetase 2 results in destabilized protein and impaired HIF-2 signaling
- Molecular validation of clinical Pantoea isolates identified by MALDI-TOF