Fungal Infections in Patients With Hematological Malignancies

Study Results

Results pending

The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.

Basic Information

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Recruitment Status

UNKNOWN

Total Enrollment

50 participants

Study Classification

OBSERVATIONAL

Study Start Date

2018-10-01

Study Completion Date

2019-10-31

Brief Summary

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\* Report the prevalence of fungal infections among patients with hematological malignancies in South Egypt Cancer Institute. \* Detect the most endemic fungal pathogen isolated from patients with hematological malignancies in South Egypt Cancer Institute. \*Antifungal susceptibility testing which guide the optimal approach to treat fungal infections. \* detection of resistant gene expression by real time PCR. \* Fungal genome sequencing analysis to determine the genetic back ground upon which mutation and resistance occur.

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Detailed Description

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Patients with hematologi¬cal malignancies are at increased risk of infections, not only because of the malignancy itself, but also because of neutropenia induced by intensive chemotherapy and its cyto¬toxic effect on the cells that line the gastrointestinal tract \[1\].

Invasive fungal infection (IFI) causes morbidity and mortality among patients with hematological malignancy.

The incidence of IFI has increased worldwide over the last two decades\[2\]. Major risk factors for IFI include neutropenia \<500 neutrophils/ml for more than 10 days, bone marrow transplantation, prolonged (\>4 wk) treatment with corticosteroids; prolonged (\>7 days) stays in intensive care, chemotherapy, HIV infection, invasive medical procedures, and the newer immune suppressive agents. Other risk factors are malnutrition, solid organ transplantation, severe burns and major surgery \[3\].

Invasive aspergillosis (IA) and invasive candidiasis are the main invasive fungal diseases associated with bloodstream Infections. Although invasive yeasts, such as Candida spp., and molds, such as Aspergillus spp., are the predominant pathogens of IFIs, other uncommon and difficult-to-treat molds, such as Mucorales, Fusarium spp., and phaeohyphomycetes, have emerged in patients with hematological malignancies \[4\].

Early initiation of the correct antifungal therapy has been demonstrated to have a direct impact on the patient's outcome\[5\]. The increased use of antifungals has induced a higher selective pressure on fungal strains and resistance has emerged in two main ways: several species have developed secondary resistance and susceptible species have been replaced by resistant ones,changing the epidemiology of fungal infections\[6\]. Among the most common mechanisms of antifungal drug resistance are changes in the biosynthetic pathways targeted by drugs \[7\]. Genomics technology and the use of DNA microarrays have facilitated the identification of targets of novel antifungal drugs\[8\]. the molecular understanding of resistance mechanisms may identify fungal genes with mutations associated with resistance. Resistance mediated by alterations in Erg11/Cyp51 (targets of azoles) has been widely documented, involving either mutations or upregulation of their genes in Candida or Aspergillus species \[9\]. Up regulation of CDR1, CDR2, and MDR1 has been demonstrated in azole-resistant C. albicans \[10\]. Genome sequencing can type known drug resistance mutations , in some cases suggesting whether particular drugs will fail to control an infection .Whole genome variants could be screened for point mutations in specific drug targets that are highly correlated with resistance . for example , specific mutations in the target of azole drugs \[11\] .or in the transcription factors that control the expression of drug efflux transporters \[12\] can be identified from whole genome sequence data only in isolates that display drug resistance \[13\]. There are two general approaches for genomic analysis of fungal pathogens. One involves generation of a genome assembly de novo, such as for a species that has not been previously sequenced and assembled. In the other approach, commonly termed re-sequencing, variants are identified between an existing reference assembly and a sequenced isolate via alignment of sequence reads to the reference. However, the choice of technology selected to generate the sequence is influenced both by the approach selected and by the goals of the study .\[14\]

Conditions

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Fungal Infection

Study Design

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Observational Model Type

COHORT

Study Time Perspective

PROSPECTIVE

Interventions

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culture on Sabouraud's Dextrose Agar (SDA)

• Clinical samples will be cultured onto Sabouraud's Dextrose Agar (SDA) plates supplemented with chloramphenicol. the culture was incubated at 25 C° and at 37° C (for yeasts and moulds isolation )

Intervention Type DIAGNOSTIC_TEST

Other Intervention Names

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E test

Eligibility Criteria

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Inclusion Criteria

* Immunocompromised adult patient with hematological malignancy , risky to fungal infection as
* patients receiving cytotoxic or immunosuppressive therapy. Patients with prolonged and deep neutropenia.
* patients exposed to prolonged use of antibiotic , prolonged Foley catheter drainage peripheral I.V catheters, corticosteroid use
* patients have presentations of fungal infection such as pulmonary infections ( pneumonia , sinusitis). and disseminated infection manifested commonly as skin lesions or soft tissue involvement .

Exclusion Criteria

* Non hematologicaly malignant patients .
* Any contraindication regarding procedure as:
* Local infection or distorted anatomy at the potential puncture site (eg, from previous surgical interventions,congenital or acquired malformations, or burns)
* Severe peripheral vascular disease of the limb involved

Minimum Eligible Age

18 Years

Maximum Eligible Age

75 Years

Eligible Sex

ALL

Accepts Healthy Volunteers

No