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101.
Sabine Kirner Philip E. Hammer D. Steven Hill Annett Altmann Ilona Fischer Laura J. Weislo Mike Lanahan Karl-Heinz van Pée James M. Ligon 《Journal of bacteriology》1998,180(7):1939-1943
Pyrrolnitrin is a secondary metabolite derived from tryptophan and has strong antifungal activity. Recently we described four genes, prnABCD, from Pseudomonas fluorescens that encode the biosynthesis of pyrrolnitrin. In the work presented here, we describe the function of each prn gene product. The four genes encode proteins identical in size and serology to proteins present in wild-type Pseudomonas fluorescens, but absent from a mutant from which the entire prn gene region had been deleted. The prnA gene product catalyzes the chlorination of l-tryptophan to form 7-chloro-l-tryptophan. The prnB gene product catalyzes a ring rearrangement and decarboxylation to convert 7-chloro-l-tryptophan to monodechloroaminopyrrolnitrin. The prnC gene product chlorinates monodechloroaminopyrrolnitrin at the 3 position to form aminopyrrolnitrin. The prnD gene product catalyzes the oxidation of the amino group of aminopyrrolnitrin to a nitro group to form pyrrolnitrin. The organization of the prn genes in the operon is identical to the order of the reactions in the biosynthetic pathway.The antibiotic pyrrolnitrin [3-chloro-4-(2′-nitro-3′-chlorophenyl)pyrrole] (PRN) is produced by many pseudomonads and has broad-spectrum antifungal activity (1, 5, 12–14, 17). PRN has been implicated as an important mechanism of biological control of fungal plant pathogens by several Pseudomonas strains (12–14), including P. fluorescens BL915, from which the prn genes were isolated (10).Tryptophan was identified as the precursor for PRN, based on the feeding of cultures with isotopically labeled and substituted tryptophan (2, 7, 8, 17, 25). Biosynthetic pathways were proposed as early as 1967 (7) and have been refined on the basis of tracer studies and the isolation of intermediates (Fig. (Fig.1)1) (2, 8, 17, 19, 23, 25). Recently, Hammer et al. (9) described the cloning and characterization of a 5.8-kb DNA region which encodes the PRN biosynthetic pathway. This DNA region confers the ability to produce PRN when expressed heterologously in Escherichia coli and contains four genes, prnABCD, each of which is required for PRN production. In the research described here, we used mutants in which each of the four genes was disrupted and strains which overexpress the individual genes to elucidate the function of each gene product in PRN biosynthesis. Open in a separate windowFIG. 1Biosynthetic pathways for PRN as proposed by van Pée et al. (23) (A) and by Chang et al. (2) (B). The reactions catalyzed by the PRN biosynthetic enzymes encoded by the prnABCD genes are indicated above the appropriate reaction arrows.
Open in a separate window
Open in a separate windowa+, PRN detected; −, PRN not detected. Hohaus et al. (11) presented additional evidence of the chlorinating activity of the prnA gene product, specifically, the chlorination of l-tryptophan to form 7-CLT by cell extracts from P. fluorescens strains which expressed the prnA gene, but which did not contain any of the other prn genes. To clarify which isomer was produced, Hohaus et al. (11) extracted 7-CLT from the bacteria and oxidized it to the corresponding indole-3-pyruvic acid with amino acid oxidases. Since the isolated 7-CLT was degraded by l-amino acid oxidase, but not by d-amino acid oxidase (11), it must be in the l configuration. The deduced amino acid sequence for prnA contains a consensus NAD binding site (9), and, indeed, NADH is a required cofactor for the prnA gene product.Cultures of BL915ΔORF2 produced 7-CLT, but 7-chloro-d-tryptophan (11) and other PRN biosynthetic intermediates were not detected (Fig. (Fig.3).3). BL915ΔORF2 produced PRN when supplied with exogenous MDA or APRN, but not when supplied with 7-CT (Table (Table2).2). When prnB was expressed in strain BL915ΔORF1–4, exogenously supplied 7-CT was converted to MDA (Fig. (Fig.4).4). These results indicate that the prnB gene product catalyzes the rearrangement of the indole ring to a phenylpyrrole and the decarboxylation of 7-CLT to convert 7-CLT to MDA. While it is somewhat surprising that a single enzyme carries out both the ring rearrangement and decarboxylation, Chang et al. (2) postulated a mechanism for such a reaction on a single enzyme some 16 years ago. The prnB gene product also catalyzed the production of APP (Fig. (Fig.4),4), presumably by using tryptophan as a substrate. Open in a separate windowFIG. 4In vivo conversion of PRN biosynthetic intermediates by the products of single prn genes. Individual genes were expressed on plasmids in the host strain BL915ΔORF1–4, and biosynthetic intermediates were added to the culture medium as indicated. Culture extracts were separated by TLC on silica plates with toluene as the mobile phase. Metabolites were visualized with van Urk’s reagent. Arrows indicate the positions of APP (dark green), MDA (olive green), APRN (reddish brown), and PRN (purple).MDA accumulated in cultures of BL915ΔORF3, but APP, APRN, and PRN were not detected (Fig. (Fig.3).3). BL915ΔORF3 was able to produce PRN when supplied with APRN in the culture medium, but not when supplied with 7-CT or MDA (Table (Table2).2). Strain BL915ΔORF1–4 expressing prnC converted exogenously supplied MDA to APRN (Fig. (Fig.4).4). These data indicate that the prnC gene product catalyzes the chlorination of MDA to form APRN. Cell extracts of the P. fluorescens strain which overexpresses the prnC gene (but does not contain the other prn genes) can also catalyze the chlorination of MDA to form APRN (11).The prnC gene is homologous to the chl gene from Streptomyces aureofaciens, which encodes a chlorinating enzyme for tetracycline biosynthesis (3, 9). Like prnA, the prnC deduced amino acid sequence contains a consensus NAD binding region (9), and NADH is required for the chlorination of MDA (11). While both prnA and prnC encode halogenating enzymes, they show no homology to previously cloned haloperoxidases (9) or to each other. Furthermore, in contrast to haloperoxidases (16), the two NADH-dependent halogenating enzymes in the PRN biosynthesis pathway are substrate specific (i.e., the tryptophan halogenase does not catalyze the chlorination of MDA and vice versa) (11).APRN accumulated in cultures of BL915ΔORF4 (Fig. (Fig.3),3), and this mutant was not able to produce PRN when supplied with any of the known PRN biosynthetic intermediates. Strain BL915ΔORF1–4 expressing prnD converted exogenously supplied APRN to PRN (Fig. (Fig.4).4). These results indicate that the prnD gene product catalyzes the oxidation of the amino group of APRN to a nitro group forming PRN. In vitro experiments by Kirner and van Pée (15) had suggested that this reaction is catalyzed by a chloroperoxidase; however, gene disruption experiments demonstrated that chloroperoxidases are not involved in PRN biosynthesis in vivo (16). Instead, this oxidation is more likely to be catalyzed by a class IA oxygenase (20), as suggested by the homology of prnD with these enzymes (9).We have shown that each prn gene encodes a protein found in the wild-type BL915 strain and have demonstrated in vivo that these four gene products carry out four biochemical steps which convert l-tryptophan to PRN. None of the conversions were observed in strain BL915ΔORF1–4, from which the entire 5.8-kb prn gene region has been deleted (Fig. (Fig.4).4). The arrangement of the genes in the operon is identical to the sequence of reactions in the biosynthetic pathway proposed by van Pée et al. (23) (Fig. (Fig.11).Chang et al. (2) proposed an alternate biosynthetic scheme (Fig. (Fig.1B)1B) and reported the conversion of exogenously supplied APP to PRN in vivo. Similarly, Zhou et al. (25) reported the conversion of APP to APRN in a cell-free system. These workers concluded that APP is an intermediate in PRN biosynthesis and that ring rearrangement precedes chlorination (Fig. (Fig.1B).1B). In the present study, APP accumulated only in strains which overexpressed the prnB gene. Furthermore, APP was not detected in cultures of BL915ΔORF1, which contains functional prnBCD genes expressed from the native promoter, as would be expected if the ring rearrangement (catalyzed by the prnB gene product) occurs before the first chlorination step (catalyzed by the prnA gene product). Like Hamill et al. (8) and van Pée et al. (23), we demonstrated that exogenously supplied 7-CT is converted to PRN. These results, together with the finding that the gene product of prnA catalyzes the NADH-dependent chlorination of l-tryptophan to 7-CLT (11), support the biosynthetic pathway proposed by van Pée et al. (23) (Fig. (Fig.1A)1A) and suggest that APP is a side product or dead-end metabolite. Purification and kinetic characterization of the prnA and prnB gene products, including investigations of substrate specificity and regioselectivity, will further clarify the roles of 7-CLT and APP in the PRN biosynthetic pathway.If APP is indeed a dead-end metabolite, it would be advantageous to tightly regulate the amount of prnB gene product present in cells, thus minimizing the diversion of substrate into APP. The prnB gene begins with GTG (9), which is a two- to threefold-less-efficient initiation codon than ATG (18); however, the prnB open reading frame is apparently translationally coupled to the prnA open reading frame (9). Coupling increases translational efficiency and is thought to be a mechanism to ensure coordinate expression of the coupled genes (18). In PRN biosynthesis, translational coupling of prnA and prnB may be a mechanism to regulate the level of prnB gene product present in cells and minimize the diversion of tryptophan to APP. 相似文献
Bacterial strains and plasmids.
The bacterial strains and plasmids used in this study are described in Table Table1.1. Pseudomonas strains were cultured in Luria-Bertani medium at 28°C. Antibiotics, when used, were added at the following concentrations: tetracycline, 30 μg/ml; and kanamycin, 50 μg/ml. The expression vector pPEH14 consists of the Ptac promoter and rrnB ribosomal terminator from pKK223-3 (Pharmacia, Uppsala, Sweden) cloned into the BglII site of the broad-host-range plasmid pRK290 (4). Ptac is a strong constitutive promoter in Pseudomonas (unpublished data). The PRN biosynthetic genes are the coding regions described by Hammer et al. (9). Each coding region was cloned from the translation initiation codon to the stop codon by PCR with restriction sites added to the ends to facilitate cloning. For prnB, the native GTG initiation codon was changed to ATG. The clones were sequenced after PCR.TABLE 1
Bacterial strains and plasmids used in this study| P. fluorescens strain or plasmid | Characteristics | Source or reference |
|---|---|---|
| Strains | ||
| BL915 | Wild type | 10 |
| BL915ΔORF1 | Deletion in prnA of BL915, Prn−, Kmr | 9 |
| BL915ΔORF2 | Deletion in prnB of BL915, Prn−, Kmr | 9 |
| BL915ΔORF3 | Deletion in prnC of BL915, Prn−, Kmr | 9 |
| BL915ΔORF4 | Deletion in prnD of BL915, Prn−, Kmr | 9 |
| BL915ΔORF1–4 | Deletion in prnABCD of BL915, Prn−, Kmr | 9 |
| Plasmids | ||
| pPEH14(prnA) | pRK290 carrying Ptac functionally fused to the 1.6-kb prnA coding region | This study |
| pPEH14(prnB) | pRK290 carrying Ptac functionally fused to the 1.1-kb prnB coding region | This study |
| pPEH14(prnC) | pRK290 carrying Ptac functionally fused to the 1.7-kb prnC coding region | This study |
| pPEH14(prnD) | pRK290 carrying Ptac functionally fused to the 1.1-kb prnD coding region | This study |
Chemical standards.
7-Cl-d,l-tryptophan (7-CT) was synthesized as described by van Pée et al. (24). Monodechloroaminopyrrolnitrin (MDA) was extracted from cultures of P. aureofaciens and verified as described by van Pée et al. (23). Aminopyrrolnitrin (APRN) was prepared from PRN by reduction with sodium dithionite (22). PRN was synthesized according to the method of Gosteli (6).Western analysis.
To produce antigen, each prn gene was subcloned into a pET3 vector and transformed into E. coli BL21(De3) (Novagen, Inc., Madison, Wis.). Inclusion bodies were purified from induced cultures with protocols from Novagen. Inclusion body protein (100 μg) was run on a preparative Laemmli polyacrylamide electrophoresis gel, blotted to nitrocellulose filters, and stained with Ponceau S. The major band was excised, solubilized in dimethyl sulfoxide, and used by Duncroft, Inc. (Lovettsville, Va.), to immunize goats and produce antiserum against each PRN protein.Cultures of P. fluorescens BL915 were grown for 48 h in Luria-Bertani medium with the appropriate antibiotics. The cells were pelleted and resuspended in a small volume of Tris-EDTA. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western analysis were performed as described by Sambrook et al. (21). The primary antiserum (goat anti-PRN protein) was diluted 1/1,000, and the secondary antibody (rabbit anti-goat immunoglobulin G conjugated to peroxidase; Pierce, Rockford, Ill.) was diluted 1/3,000. Bands were visualized with an enhanced chemiluminescence kit (Amersham, Arlington Heights, Ill.). This Western analysis demonstrated that each antibody recognized a single protein band from wild-type BL915, and these bands were not present in BL915ΔORF1–4 (Fig. (Fig.2).2). The molecular weights of the recognized proteins were consistent with the sizes predicted from the gene sequences. Each prn gene was expressed on a plasmid in BL915ΔORF1–4. In each case, the protein product of the cloned gene reacted only with the expected antibody and was identical in size to the band detected by that antibody in wild-type BL915 (Fig. (Fig.2).2). Open in a separate windowFIG. 2Western blot analysis of the protein products of prn genes cloned from P. fluorescens BL915. Individual genes were expressed on plasmids in the host strain BL915ΔORF1–4. BL915 wild-type and BL915ΔORF1–4 controls are included on each blot. Blots A, B, C, and D were probed with antibodies raised against the products of prnA, prnB, prnC, and prnD, respectively. Arrows indicate the positions of the 60- and 42-kDa molecular mass markers.Intermediate analysis and feeding experiments.
To determine which biosynthetic intermediates were produced by the prn gene deletion mutants, 2-day-old cultures were extracted with an equal volume of ethyl acetate. The organic phase was dried under vacuum, and the residue was dissolved in a small volume of methanol. Thin-layer chromatography (TLC) was performed on silica-coated plates with toluene or hexane-ethyl acetate (2:1) as the mobile phase. PRN, APRN, MDA, and aminophenylpyrrole (APP) were visualized with van Urk’s reagent as described previously (22).To further clarify which biosynthetic step was blocked in each deletion mutant, intermediate feeding experiments were conducted. Cultures (10 ml) were incubated at 28°C for 48 h. Biosynthetic intermediates were dissolved in a small volume of methanol and added to 4 ml of culture at the following final concentrations: 7-CT, 2.5 μg/ml; MDA, 25 μg/ml; APRN, 12.5 μg/ml. The cultures were incubated for an additional 4 h at 28°C and then extracted with ethyl acetate and analyzed by TLC and liquid chromatography-mass spectrometry as described above.MDA, APRN, and PRN were not detected in cultures of BL915ΔORF1 (Fig. (Fig.3),3), indicating that this mutant is blocked at an early step in PRN biosynthesis. BL915ΔORF1 was able to produce PRN when 7-CT, MDA, or APRN was supplied exogenously (Table (Table2).2). When prnA was expressed in the absence of other prn genes (i.e., in BL915ΔORF1–4), 7-chloro-l-tryptophan (7-CLT) accumulated. The identity of 7-CLT was verified by comparison of results of high-performance liquid chromatography and mass spectra with chemically synthesized 7-CT. These results indicate that the prnA gene product catalyzes the chlorination of l-tryptophan. Open in a separate windowFIG. 3Accumulation of PRN biosynthetic intermediates in P. fluorescens BL915 and prn gene deletion mutants derived from it. Extracts from 2-day-old cultures were separated by TLC on silica plates with hexane-ethyl acetate (2:1 [vol/vol]) as the mobile phase. Metabolites were visualized with van Urk’s reagent. Arrows indicate the positions of MDA (olive green), APRN (reddish brown), and PRN (purple).TABLE 2
Production of PRN by deletion mutants when supplied with biosynthetic intermediates in the growth medium| Strain | Result with intermediate added to culturesa
| ||
|---|---|---|---|
| 7-CT | MDA | APRN | |
| BL915ΔORF1 | + | + | + |
| BL915ΔORF2 | − | + | + |
| BL915ΔORF3 | − | − | + |
| BL915ΔORF4 | − | − | − |
102.
Induced Levels of Heat Shock Proteins in a dnaK Mutant of Lactococcus lactis 总被引:1,自引:0,他引:1 
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下载免费PDF全文 Birgit Koch Mogens Kilstrup Finn K. Vogensen Karin Hammer 《Journal of bacteriology》1998,180(15):3873-3881
The bacterial heat shock response is characterized by the elevated expression of a number of chaperone complexes and proteases, including the DnaK-GrpE-DnaJ and the GroELS chaperone complexes. In order to investigate the importance of the DnaK chaperone complex for growth and heat shock response regulation in Lactococcus lactis, we have constructed two dnaK mutants with C-terminal deletions in dnaK. The minor deletion of 65 amino acids in the dnaKΔ2 mutant resulted in a slight temperature-sensitive phenotype. BK6, containing the larger deletion of 174 amino acids (dnaKΔ1), removing the major part of the inferred substrate binding site of the DnaK protein, exhibited a pronounced temperature-sensitive phenotype and showed altered regulation of the heat shock response. The expression of the heat shock proteins was increased at the normal growth temperature, measured as both protein synthesis rates and mRNA levels, indicating that DnaK could be involved in the regulation of the heat shock response in L. lactis. For Bacillus subtilis, it has been found (A. Mogk, G. Homuth, C. Scholz, L. Kim, F. X. Schmid, and W. Schumann, EMBO J. 16:4579–4590, 1997) that the activity of the heat shock repressor HrcA is dependent on the chaperone function of the GroELS complex and that a dnaK insertion mutant has no effect on the expression of the heat shock proteins. The present data from L. lactis suggest that the DnaK protein could be involved in the maturation of the homologous HrcA protein in this bacterium. 相似文献
103.
Out of Africa and back again: nested cladistic analysis of human Y chromosome variation 总被引:18,自引:3,他引:15
Hammer MF; Karafet T; Rasanayagam A; Wood ET; Altheide TK; Jenkins T; Griffiths RC; Templeton AR; Zegura SL 《Molecular biology and evolution》1998,15(4):427-441
We surveyed nine diallelic polymorphic sites on the Y chromosomes of 1,544
individuals from Africa, Asia, Europe, Oceania, and the New World.
Phylogenetic analyses of these nine sites resulted in a tree for 10
distinct Y haplotypes with a coalescence time of approximately 150,000
years. The 10 haplotypes were unevenly distributed among human populations:
5 were restricted to a particular continent, 2 were shared between Africa
and Europe, 1 was present only in the Old World, and 2 were found in all
geographic regions surveyed. The ancestral haplotype was limited to African
populations. Random permutation procedures revealed statistically
significant patterns of geographical structuring of this paternal genetic
variation. The results of a nested cladistic analysis indicated that these
geographical associations arose through a combination of processes,
including restricted, recurrent gene flow (isolation by distance) and range
expansions. We inferred that one of the oldest events in the nested
cladistic analysis was a range expansion out of Africa which resulted in
the complete replacement of Y chromosomes throughout the Old World, a
finding consistent with many versions of the Out of Africa Replacement
Model. A second and more recent range expansion brought Asian Y chromosomes
back to Africa without replacing the indigenous African male gene pool.
Thus, the previously observed high levels of Y chromosomal genetic
diversity in Africa may be due in part to bidirectional population
movements. Finally, a comparison of our results with those from nested
cladistic analyses of human mtDNA and beta-globin data revealed different
patterns of inferences for males and females concerning the relative roles
of population history (range expansions) and population structure
(recurrent gene flow), thereby adding a new sex-specific component to
models of human evolution.
相似文献
104.
105.
Aron J. Huckaba Fabrizio Giordano Louis E. McNamara Katelyn M. Dreux Nathan I. Hammer Gregory S. Tschumper Shaik M. Zakeeruddin Michael Grätzel Mohammad K. Nazeeruddin Jared H. Delcamp 《Liver Transplantation》2015,5(7)
Strong electron‐donating functionality is desirable for many organic donor‐π‐bridge‐acceptor (D‐π‐A) dyes. Strategies for increasing the electron‐donating strength of common nitrogen‐based donors include planarization of nitrogen substituents and the use of low resonance‐stabilized energy aromatic ring‐substituted nitrogen atoms. Organic donor motifs based on the planar nitrogen containing heterocycle indolizine are synthesized and incorporated into dye‐sensitized solar cell (DSC) sensitizers. Resonance active substitutions at several positions on indolizine in conjugation with the D‐π‐A π‐system are examined computationally and experimentally. The indolizine‐based donors are observed to contribute electron density with strengths greater than triarylamines and diarylamines, as evidenced by UV/Vis, IR absorptions, and oxidation potential measurements. Fluorescence lifetime studies in solution and on TiO2 yield insights in understanding the performance of indolizine‐based dyes in DSC devices. 相似文献
106.
Theresa Pohlkamp Murat Durakoglugil Courtney Lane-Donovan Xunde Xian Eric B. Johnson Robert E. Hammer Joachim Herz 《PloS one》2015,10(2)
Apolipoprotein E (ApoE) genotype is the strongest predictor of Alzheimer’s Disease (AD) risk. ApoE is a cholesterol transport protein that binds to members of the Low-Density Lipoprotein (LDL) Receptor family, which includes LDL Receptor Related Protein 4 (Lrp4). Lrp4, together with one of its ligands Agrin and its co-receptors Muscle Specific Kinase (MuSK) and Amyloid Precursor Protein (APP), regulates neuromuscular junction (NMJ) formation. All four proteins are also expressed in the adult brain, and APP, MuSK, and Agrin are required for normal synapse function in the CNS. Here, we show that Lrp4 is also required for normal hippocampal plasticity. In contrast to the closely related Lrp8/Apoer2, the intracellular domain of Lrp4 does not appear to be necessary for normal expression and maintenance of long-term potentiation at central synapses or for the formation and maintenance of peripheral NMJs. However, it does play a role in limb development. 相似文献
107.
Alexa Orand Arpana Gupta Wendy Shih Angela P. Presson Christian Hammer Beate Niesler Nuwanthi Heendeniya Emeran A. Mayer Lin Chang 《PloS one》2015,10(8)
Background
Genetic and environmental factors contribute to the pathophysiology of irritable bowel syndrome (IBS). In particular, early adverse life events (EALs) and the catecholaminergic system have been implicated.Aims
To investigate whether catecholaminergic SNPs with or without interacting with EALs are associated with: 1) a diagnosis of IBS, 2) IBS symptoms and 3) morphological alterations in brain regions associated with somatosensory, viscerosensory, and interoceptive processes.Methods
In 277 IBS and 382 healthy control subjects (HCs), 11 SNPs in genes of the catecholaminergic signaling pathway were genotyped. A subset (121 IBS, 209 HCs) underwent structural brain imaging (magnetic resonance imaging [MRI]). Logistic and linear regressions evaluated each SNP separately and their interactions with EALs in predicting IBS and GI symptom severity, respectively. General linear models determined grey matter (GM) alterations from the SNPs and EALs that were predictive of IBS.Results
1) Diagnosis: There were no statistically significant associations between the SNPs and IBS status with or without the interaction with EAL after adjusting for multiple comparisons. 2) Symptoms: GI symptom severity was associated with ADRA1D rs1556832 (P = 0.010). 3) Brain morphometry: In IBS, the homozygous genotype of the major ADRA1D allele was associated with GM increases in somatosensory regions (FDR q = 0.022), left precentral gyrus (q = 0.045), and right hippocampus (q = 0.009). In individuals with increasing sexual abuse scores, the ADRAβ2 SNP was associated with GM changes in the left posterior insula (q = 0.004) and left putamen volume (q = 0.029).Conclusion
In IBS, catecholaminergic SNPs are associated with symptom severity and morphological changes in brain regions concerned with sensory processing and modulation and affect regulation. Thus, certain adrenergic receptor genes may facilitate or worsen IBS symptoms. 相似文献108.
Niels Hammer Robert M?bius André Gries Bj?rn Hossfeld Ingo Bechmann Michael Bernhard 《PloS one》2015,10(12)
Introduction
Intraosseous infusion is recommended if peripheral venous access fails for cardiopulmonary resuscitation or other medical emergencies. The aim of this study, using body donors, was to compare a semi-automatic (EZ-IO®) device at two insertion sites and a sternal intraosseous infusion device (FASTR™).Methods
Twenty-seven medical students being inexperienced first-time users were randomized into three groups using EZ-IO and FASTR. The following data were evaluated: attempts required for successful placement, insertion time and flow rates with and without external pressure to the infusion.Results
The first-pass insertion success of the EZ-IO tibia, EZ-IO humerus and FASTR was 91%, 77%, and 95%, respectively. Insertion times (MW±SD) did not show significant differences with 17±7 (EZ-IO tibia) vs. 29±42 (EZ-IO humerus) vs. 33±21 (FASTR), respectively. One-minute flow rates using external pressures between 0 mmHg and 300 mmHg ranged between 27±5 to 69±54 ml/min (EZ-IO tibia), 16±3 to 60±44 ml/min (EZ-IO humerus) and 53±2 to 112±47 ml/min (FASTR), respectively. Concerning pressure-related increases in flow rates, negligible correlations were found for the EZ-IO tibia in all time frames (c = 0.107–0.366; p≤0.013), moderate positive correlations were found for the EZ-IO humerus after 5 minutes (c = 0.489; p = 0.021) and strong positive correlations were found for the FASTR in all time frames (c = 0.63–0.80; p≤0.007). Post-hoc statistical power was 0.62 with the given sample size.Conclusions
The experiments with first-time users applying EZ-IO and FASTR in body donors indicate that both devices may be effective intraosseous infusion devices, likely suitable for fluid resuscitation using a pressure bag. Variations in flow rate may limit their reliability. Larger sample sizes will prospectively be required to substantiate our findings. 相似文献109.
110.