[Waiting time to transcatheter aortic valve implantation (TAVI) and mortality during wait period in Algeria]. / Délais d'attente d'implantation de valve aortique transcutanée (TAVI) et mortalité durant la période d'attente en Algérie.

BACKGROUND: Trans Aortic Valve Implantation (TAVI) has become the primary treatment for aortic stenosis in patients over 75 years old. Despite its clinical efficacy, it's adoption in emerging countries remains low due to the high cost of prostheses and limited healthcare funding resources. This leads to prolonged waiting times for the TAVI procedure, which may lead to complications; these data are missing particularly in emerging countries. AIMS: To describe waiting time for TAVI and mortality rate in this waiting period. MATERIALS AND METHODS: This was prospective registry, patients referred for TAVI were prospectively followed; waiting time was calculated from the first visit after referral to TAVI implantation, clinical and, call fellow up was performed every 3 months. We divided patients into two groups: Group 1 (G1) patients still awaiting TAVI (105 patients), and those who underwent TAVI (36 patients). Group 2 (G2) patients who died while awaiting TAVI (16 patients, 10,2 %). RESULTS: Demographic characteristics were similar, with a tendency for older age in G2 (79.5 ± 5.7 years vs. 82.5 ± 7.4 years, p=0,06). G2 exhibited more left ventricular ejection fraction (LVEF) impairment (8.5% vs. 25%, p=0,03) and a higher rate of severe heart failure with dyspnea stages III or IV (2.8% vs. 12.5%, p<0,001). The mean follow-up in G1 was 242.9 ± 137.4 days; the waiting time for TAVI was 231.7 ± 134.1 days, and the average time between the first consultation and death while awaiting TAVI (G2) was 335.1 ± 167.4 days. CONCLUSION: in our series, waiting time is high due to limited Trans aortic heart valve availability, mortality during this wait exceeds 10%. Adverse prognostic factors include impaired LVEF and severe dyspnea stages III or IV.

Single or double mutational alterations of gyrA associated with fluoroquinolone resistance in Campylobacter jejuni and Campylobacter coli.

We looked for the presence of gyrA mutations in seven fluoroquinolone-resistant French clinical isolates of Campylobacter jejuni and Campylobacter coli. Three of the five isolates of C. jejuni and the two isolates of C. coli had high-level resistance to nalidixic acid (MICs 128-256 microg/ml) and ciprofloxacin (MICs 32 microg/ml). A gyrA mutation was found in all these isolates leading to the following substitutions: Thr86-Ile in four cases and Asp90-Tyr for one C. coli strain. One isolate had high-level resistance to nalidixic acid (MIC 64 microg/ml) but low-level resistance to ciprofloxacin (MIC 2 microg/ml) and also carried a gyrA mutation leading to a Thr86-Ala substitution. The last isolate of C. jejuni studied displayed an atypical resistance phenotype: It was resistant to high levels of ciprofloxacin (MIC 64 microg/ml) but remained fully susceptible to nalidixic acid (MIC 2 microg/ml). This phenotype was not explained by the presence of peculiar mutations in gyrA or gyrB. It carried a gyrA mutation leading to a Thr86-Ile substitution and was devoid of gyrB mutation. Despite numerous attempts with various degenerate oligonucleotide primers deduced from conserved regions of known parC genes, we were unable to amplify a corresponding sequence in C. jejuni or C. coli. First-step and second-step in vitro mutants, derived from reference strain C. coli ATCC 33559 with ciprofloxacin or moxifloxacin as selecting agents, were found to carry one and two mutations in gyrA, respectively. In contrast with the results obtained with clinical isolates, a variety of gyrA mutations were obtained in vitro.

In-vitro activity of moxifloxacin against fluoroquinolone-resistant strains of aerobic gram-negative bacilli and Enterococcus faecalis.

MICs of the new fluoroquinolone, moxifloxacin, and those of ciprofloxacin, ofloxacin and sparfloxacin for 19 genetically characterized fluoroquinolone-resistant strains were determined by the agar dilution method. The MICs of moxifloxacin for Escherichia isolates with one mutation in gyrA (corresponding to Ser83-->Leu or Asp87-->Gly substitution) were 0.25-0.5 mg/L, while those of ciprofloxacin, ofloxacin and sparfloxacin were 0.06-0.25, 1 and 0.12-0.5 mg/L, respectively. These values were four- to 16-fold higher than those of the same antibiotics for the wild-type strain, E. coli KL16. Similar results were observed with clinical isolates of Salmonella spp. harbouring one mutation in gyrA leading to the substitution of Ser83 by Phe or Tyr. In the presence of two mutations in the E. coli gyrA gene, the MICs of moxifloxacin ciprofloxacin, ofloxacin and sparfloxacin were 2, 0.5, 4 and 1 mg/L, respectively; these were 32 times higher than the MICs of these agents for E. coli KL16. The MICs of the four quinolones for triple mutants with two mutations in gyrA and one in parC were even higher, i.e. 8, 8, 16 and 8-16 mg/L, respectively. The MICs of moxifloxacin for Campylobacter coli and Campylobacter jejuni strains with a gyrA mutation leading to Thr86-->Ile substitution ranged from 1 to 2 mg/L, while the MICs of ciprofloxacin, ofloxacin and sparfloxacin were 16-32 mg/L, 8-16 and 4-8 mg/L, respectively. For high-level ciprofloxacin-resistant (MICs of 32 mg/L) clinical isolates of Enterococcus faecalis with one substitution at position 83 in GyrA (E. coli coordinates), the MICs of moxifloxacin, ofloxacin and sparfloxacin were 8-16, > or = 128 and 32 mg/L respectively. In conclusion, moxifloxacin and other fluoroquinolones exhibit cross-resistance against aerobic gram-negative bacilli and enterococci. The in-vitro activity of moxifloxacin was greater than that of ofloxacin and slightly less than that of ciprofloxacin and sparfloxacin against Enterobacteriaceae, but greater than those of the three other compounds tested against Campylobacter spp and E. faecalis.

Quinolone resistance locus nfxD of Escherichia coli is a mutant allele of the parE gene encoding a subunit of topoisomerase IV.

The locus nfxD, which contributes to high-level quinolone resistance in Escherichia coli KF111b (gyrAr nfxB nfxD), is only expressed in the presence of a gyrA mutation, and maps to the region of the parC and parE genes, was outcrossed into strain KF130, creating strain DH161 (gyrAr nfxD). DNA sequence analysis of DH161 revealed no changes in the topoisomerase IV parC quinolone resistance-determining region but did identify a single T-to-A mutation in parE at codon 445, leading to a change from Leu to His. Full-length cloned parE+ partially complemented the resistance phenotype in KF111b and DH161, but did not complement the resistance phenotype in strain KF130 (gyrAr). No complementation was seen with cloned, truncated parE+. To confirm these findings, gyrAr was first outcrossed from KF130 into E. coli W3110parE10 [parE temperature sensitive(Ts)] and KL16. The transduced strains KL16 and W3110parE10 were subsequently transformed with plasmids containing cloned parE from DH161 or KL16. Cloned parE from DH161 increased norfloxacin resistance in the parE(Ts) background twofold at 30 degrees C and fourfold at 42 degrees C compared to those for cloned parE from KL16. The same experiment with a non-Ts background revealed a twofold increase in the norfloxacin MIC at both 30 and 42 degrees C. These data identify the nfxD conditional resistance locus as a mutant allele of parE. This report is the first of a quinolone-resistant parE mutant and confirms the role of topoisomerase IV as a secondary target of norfloxacin in E. coli.

Quinolone resistance mutations in the gyrA gene of clinical isolates of Salmonella.

S. typhimurium AlhR, S. enteritidis OulR, and S. hadar GueR resistant to fluoroquinolones (QR), ciprofloxacin MICs, 0.25 to 1 microgram/ml; norfloxacin MICs, 0.5 to 4 micrograms/ml; nalidixic acid MIC, 256 micrograms/ml were isolated from urinary tract infections (AlhR and OulR) during FQ therapy in immunocompromised patients infected by the parent FQ-susceptible strains (AlhS and OulS) (ciprofloxacin MICs, 0.032-0.063; norfloxacin MICs, 0.125-0.25; nalidixic acid MICs, 4-8) or from intestinal infection (GueR). Transformation of AlhR, OulR, and GueR by plasmid pJSW101 carrying the wild-type gyrA gene of Escherichia coli resulted in complementation (nalidixic acid MICs, 4 to 8), proving that these strains had a gyrA mutation. A 800-bp fragment of gyrA from the five strains was amplified by PCR. Direct DNA sequencing of 252-bp region of this fragment identified a single point mutation leading to a substitution Ser-83 to Tyr in AlhR and to a substitution Ser-83 to Phe in OulR and in GueR. These results emphasize the potential risk of selection of FQ-resistant Salmonella during FQ therapy in immunocompromised patients and suggest that these strains differ from the parent strains at least by one mutation in the gyrA gene. They also confirm the role of substitutions in position 83 of gyrA in FQ-resistant clinical isolates of Salmonella.

Sequential mutations of gyrA in Escherichia coli associated with quinolone therapy.

A clinical isolate of Escherichia coli HM73 (MIC norfloxacin 2 mg/L) was isolated during norfloxacin therapy from an urinary tract infection in a patient who had been previously treated with pipemidic acid and infected by E. coli HM72 (norfloxacin 0.25), known to harbour a substitution Ser 83-->Leu in the gyrA gene. No difference in accumulation of norfloxacin was found between the two strains. DNA gyrases were isolated by affinity chromatography and assayed for supercoiling activity in the presence of norfloxacin. The minimal effective doses (MEDs) were 20 mg/L, for HM72 and 80 for HM73. DNA sequencing identified in HM73, two mutations leading to substitutions Ser 83 to Leu and Asp 87 to Gly.

Detection of gyrA and gyrB mutations in quinolone-resistant clinical isolates of Escherichia coli by single-strand conformational polymorphism analysis and determination of levels of resistance conferred by two different single gyrA mutations.

Twelve quinolone-resistant clinical isolates of Escherichia coli (nalidixic acid MICs, 64 to 512 micrograms/ml; norfloxacin MICs, 0.25 to 8 micrograms/ml) were transformed with plasmid pJSW101 carrying the gyrA+ gene and with plasmid pJB11 carrying the gyrB+ gene to examine the proportion of gyrA and gyrB mutations. Transformation with pJSW101 resulted in complementation (nalidixic acid MICs, 4 to 32 micrograms/ml; norfloxacin MICs, 0.06 to 0.25 micrograms/ml). In contrast, no change in MICs were observed after transformation with pJB11. A 418-bp fragment of gyrA from the 12 strains was amplified by PCR. Direct DNA sequencing of that fragment identified the causes of quinolone resistance in eight strains as a single point mutation leading to a substitution of the serine at position 83 (Ser-83) to Leu and in four strains as a single point mutation leading to a substitution of Asp-87 to Gly. Exchange of the fragment from one of these strains with that of gyrA+ and transformation of resistance with the hybrid gyrA plasmid indicated the contribution of Gly-87 to resistance and the stabilities of mutants containing GyrA (Gly-87). Thus, gyrA gene mutations are probably encountered more often than gyrB gene mutations in clinical isolates of E. coli. In addition, the substitution of Asp-87 to Gly can be encountered in such strains. On the basis of the level of resistance found in the fragment exchange experiment, the quinolone resistance attributable to Gly-87 appears to be comparable to that attributable to Leu-83. The levels of resistance found in the clinical isolates shown to have a Gly-87 mutation (nalidixic acid MICs, 64 to 512 micrograms/ml; norfloxacin MICs, 0.5 to 4 micrograms/ml) suggest that the Gly-87 mutation causes resistance at the level of the nalidixic acid MIC (64 micrograms/ml) or the norfloxacin MIC (0.5 micrograms/ml or less) and that the additional increments in resistance seen in the other strains with higher levels of resistance may be attributable to additional mutations. The single-strand conformational polymorphism analysis with PCR products readily detected te Leu-83 and Gly-87 mutations.