Interventions to prevent iatrogenic anemia: a Laboratory Medicine Best Practices systematic review.

BACKGROUND: As many as 90% of patients develop anemia by their third day in an intensive care unit (ICU). We evaluated the efficacy of interventions to reduce phlebotomy-related blood loss on the volume of blood lost, hemoglobin levels, transfusions, and incidence of anemia. METHODS: We conducted a systematic review and meta-analysis using the Laboratory Medicine Best Practices (LMBP) systematic review methods for rating study quality and assessing the body of evidence. Searches of PubMed, Embase, Cochrane, Web of Science, PsychINFO, and CINAHL identified 2564 published references. We included studies of the impact of interventions to reduce phlebotomy-related blood loss on blood loss, hemoglobin levels, transfusions, or anemia among hospital inpatients. We excluded studies not published in English and studies that did not have a comparison group, did not report an outcome of interest, or were rated as poor quality. Twenty-one studies met these criteria. We conducted a meta-analysis if > 2 homogenous studies reported sufficient information for analysis. RESULTS: We found moderate, consistent evidence that devices that return blood from flushing venous or arterial lines to the patient reduced blood loss by approximately 25% in both neonatal ICU (NICU) and adult ICU patients [pooled estimate in adults, 24.7 (95% CI = 12.1-37.3)]. Bundled interventions that included blood conservation devices appeared to reduce blood loss by at least 25% (suggestive evidence). The evidence was insufficient to determine if these devices reduced hemoglobin decline or risk of anemia. The evidence suggested that small volume tubes reduced the risk of anemia, but was insufficient to determine if they affected the volume of blood loss or the rate of hemoglobin decline. CONCLUSIONS: Moderate, consistent evidence indicated that devices that return blood from testing or flushing lines to the patient reduce the volume of blood loss by approximately 25% among ICU patients. The results of this systematic review support the use of blood conservation systems with arterial or venous catheters to eliminate blood waste when drawing blood for testing. The evidence was insufficient to conclude the devices impacted hemoglobin levels or transfusion rates. The use of small volume tubes may reduce the risk of anemia.

Rapid influenza diagnostic test use and antiviral prescriptions in outpatient settings pre- and post-2009 H1N1 pandemic.

BACKGROUND: Rapid influenza diagnostic tests (RIDTs) can be used at the point-of-care and are often the only influenza tests readily available in outpatient facilities. OBJECTIVES: To determine the use of RIDTs and antiviral prescription practices in outpatient facilities. STUDY DESIGN: Surveys were mailed to U.S. physician's offices, emergency departments, and community health centers in 2008 (pre-2009 H1N1 pandemic) and 2010 (post-2009 H1N1 pandemic). The 2010 survey included questions to evaluate changes in testing and treatment practices among various risk groups subsequent to the 2009 H1N1 pandemic. RESULTS: In both surveys, respondents using RIDTs relied on RIDT results to guide prescribing antiviral medications. Greater than two-thirds of these respondents reported prescribing antiviral medications both pre- and post-pandemic for patients within 48h of onset of flu-like symptoms with a positive RIDT (69% pre-pandemic; 67% post-pandemic). After the pandemic (2010 survey), outpatient providers also reported prescribing antivirals to those with flu-like symptoms for 31% of children <2 years, 23% of children 2-5 years, 37% of pregnant patients, and 74% of other patients at high risk; while these figures were higher than pre-pandemic, they represent a failure to use CDC guidelines to prescribe antivirals for patients with suspected influenza who are at higher risk for complications. CONCLUSIONS: Clinicians in outpatient facilities often relied on RIDT findings to aid in making antiviral treatment decisions; however their treatment practices were not always consistent with CDC guidelines. The use of RIDTs and antiviral medicines were influenced by the 2009 H1N1 pandemic.

KPC-4 Is encoded within a truncated Tn4401 in an IncL/M plasmid, pNE1280, isolated from Enterobacter cloacae and Serratia marcescens.

We describe the transfer of bla(KPC-4) from Enterobacter cloacae to Serratia marcescens in a single patient. DNA sequencing revealed that KPC-4 was encoded on an IncL/M plasmid, pNE1280, closely related to pCTX-M360. Further analysis found that KPC-4 was encoded within a novel Tn4401 element (Tn4401f) containing a truncated tnpA and lacking tnpR, ISKpn7 left, and Tn4401 IRL-1, which are conserved in other Tn4401 transposons. This study highlights the continued evolution of Tn4401 transposons and movement to multiple plasmid backbones that results in acquisition by multiple species of Gram-negative bacilli.

Origins and development of the National Laboratory System for public health testing.

Although not recognized as such, a National Laboratory System (NLS) has existed since the inception of public health laboratory (PHL) testing more than a century ago. The NLS has always relied upon the participation of clinical laboratories, both to report test results that represent public health threats and to submit specimens and isolates to PHLs for additional or confirmatory testing. Historically, a number of factors have hindered the strengthening of the relationships between clinical laboratories and PHLs, but the reality of bioterrorism and subsequent focus on strengthening public-private relationships has stimulated the development of a more robust NLS. Since 2002, there has been substantial strengthening of the NLS through the sharing of lessons learned from several demonstration projects. There is a growing emphasis on defining critical elements of the NLS, including the State Public Health Laboratory System (SPH Laboratory System) and the functions of the Laboratory Program Advisor, a position that every state should have at the center of its laboratory system's capacity-building. Additional strengthening of the NLS is occurring through (1) national biennial measurement of state PHLs' abilities to meet the Core Functions and Capabilities of State PHLs, (2) the new Laboratory System Improvement Program (L-SIP) for the SPH Laboratory System, and (3) sharing ideas to integrate and improve the SPH Laboratory System (e.g., using the L-SIP Online Resource Center). Public health emergencies, such as the recent H1N1 epidemic, illustrate and reinforce the need for a strong NLS within which federal, public health, and clinical (i.e., hospital and private reference) laboratories function in close collaboration.

Developing a sustainable process to provide quality control materials for genetic testing.

PURPOSE: To provide a summary of the outcomes of two working conferences organized by the Centers for Disease Control and Prevention (CDC), to develop recommendations for practical, sustainable mechanisms to make quality control (QC) materials available to the genetic testing community. METHODS: Participants were selected to include experts in genetic testing and molecular diagnostics from professional organizations, government agencies, industry, laboratories, academic institutions, cell repositories, and proficiency testing (PT)/external Quality Assessment (EQA) programs. Current efforts to develop QC materials for genetic tests were reviewed; key issues and areas of need were identified; and workgroups were formed to address each area of need and to formulate recommendations and next steps. RESULTS: Recommendations were developed toward establishing a sustainable process to improve the availability of appropriate QC materials for genetic testing, with an emphasis on molecular genetic testing as an initial step. CONCLUSIONS: Improving the availability of appropriate QC materials is of critical importance for assuring the quality of genetic testing, enhancing performance evaluation and PT/EQA programs, and facilitating new test development. To meet the needs of the rapidly expanding capacity of genetic testing in clinical and public health settings, a comprehensive, coordinated program should be developed. A Genetic Testing Quality Control Materials Program has therefore been established by CDC in March 2005 to serve these needs.

Genetically characterized positive control cell lines derived from residual clinical blood samples.

BACKGROUND: Positive control materials for clinical diagnostic molecular genetic testing are in critically short supply. High-quality DNA that closely resembles DNA isolated from patient specimens can be obtained from Epstein-Barr virus (EBV)-transformed peripheral blood lymphocyte cell lines. Here we report the development of a process to (a) recover residual blood samples with clinically important mutations detected during routine medical care, (b) select samples likely to provide viable lymphocytes for EBV transformation, (c) establish stable cell lines and confirm the reported mutation(s), and (d) validate the cell lines for use as positive controls in clinical molecular genetic testing applications. METHODS: A network of 32 genetic testing laboratories was established to obtain anonymous, residual clinical samples for transformation and to validate resulting cell lines for use as positive controls. Three panel meetings with experts in molecular genetic testing were held to evaluate results and formulate a process that could function in the context of current common practices in molecular diagnostic testing. RESULTS: Thirteen laboratories submitted a total of 113 residual clinical blood samples with mutations for 14 genetic disorders. Forty-one EBV-transformed cell lines were established. Thirty-five individual point and deletion mutations were shown to be stable after 20 population doublings in culture. Thirty-three cell lines were characterized for specific mutations and validated for use as positive controls in clinical diagnostic applications. CONCLUSIONS: A process for producing and validating positive control cell lines from residual clinical blood samples has been developed. Sustainable implementation of the process could help alleviate the current shortage of positive control materials.

A novel method for creating artificial mutant samples for performance evaluation and quality control in clinical molecular genetics.

The lack of readily available, patient-derived materials for molecular genetic testing of many heterozygous or rare disorders creates a major impediment for laboratory proficiency and quality control procedures. The paucity of clinically derived mutation-positive samples could be surmounted if it were possible to construct artificial samples containing mutations of interest that would sufficiently resemble natural human samples. Such samples could then function as acceptable and realistic performance evaluation challenges and quality control reagents for recipient laboratories. Using the cystic fibrosis gene (CFTR) as a prototype, we have devised and executed experiments designed to generate unique DNA samples that could be used for these purposes. We used site-directed mutagenesis to generate mutations of interest in plasmid DNA derived from common bacterial artificial chromosome sources containing the cystic fibrosis transmembrane conductance receptor gene. CFTR mutations G85E and 1078delT were chosen to represent mutations in the original American College of Medical Genetics-recommended population-screening panel of 25 mutations. DNA samples containing predetermined concentrations and ratios of wild-type and mutated plasmids, bacterial artificial chromosomes of interest, and nonhuman genomic carrier DNA were characterized and tested in-house and in a group of nine pilot testing laboratories using a variety of technical platforms. The results indicate that these constructs, containing CFTR mutations in heterozygous and homozygous states, can serve as valid and accessible materials for quality assurance, including performance evaluation, proficiency testing, and assay quality control.

Assessment of laboratory performance of nucleic acid amplification tests for detection of Mycobacterium tuberculosis.

During implementation of the Centers for Disease Control and Prevention's Mycobacterium tuberculosis nucleic acid amplification (NAA) evaluation program, 27.1% of participants used the same biological safety cabinet for NAA and specimen processing; 28.8% reported not using unidirectional workflow. An association between false positives and adverse responses to quality assurance questions (P = 0.04) illustrated the need for following NCCLS recommendations.

Quality assurance in human molecular genetics testing: status and recommendations.

OBJECTIVE: The role of genetic testing has expanded with rapidly developing technology and completion of the International Human Genome Project. Development of universally acceptable quality control methods and quality assurance standards trails technology. The principle that high-quality genetic testing is important for public health motivated the Centers for Disease Control and Prevention to formulate ways for improving quality assurance of human molecular genetics testing. PARTICIPANTS: Twenty-eight panelists were chosen based on expertise in molecular genetics testing and knowledge of quality assurance practices. Representatives of professional organizations, industries, and federal agencies participated in one or more of 3 panel meetings. Consensus recommendations were developed by the 15 panelists in the third meeting. EVIDENCE: Evidence was derived from experts' opinion during 3 panel meetings. Data compiled through laboratory visits and literature review were used as reference information. Need for this project was derived from the Final Report of the Task Force on Genetic Testing, produced by the National Institutes of Health and the Department of Energy in 1997, and the Summary Report of the Subcommittee Meeting on Genetics of the Clinical Laboratory Improvement Act Advisory Committee in 1997. CONSENSUS PROCESS: Research and development needs were identified using a participatory visioning approach. A modified nominal group process was used to reach consensus. CONCLUSIONS: Five core consensus recommendations were made: research for developing positive samples for quality assurance purposes, performance evaluation programs supplementing those in existence, establishment and support of laboratory-oriented consortia, establishment of a laboratory-focused database, and support of molecular genetics training programs.

Establishment of stably EBV-transformed cell lines from residual clinical blood samples for use in performance evaluation and quality assurance in molecular genetic testing.

Positive control materials for clinical molecular genetic testing applications are currently in critically short supply or non-existent for many genetically based diseases of public health importance. Here we demonstrate that anonymous, residual, clinical blood samples are potential sources of viable lymphocytes for establishing Epstein-Barr virus (EBV)-transformed blood lymphocyte cell lines. We attempted to transform 34 residual blood samples, and analyzed transformation success with respect to sample age, anticoagulant, storage temperature, volume, hemolysis, and patient age and sex. In univariate analysis, sample age was significantly associated with transformation success (P = 0.002). The success rate was 67% (6 of 9) for samples 1 to 7 days old, 38% (3 of 8) for samples 8 to 14 days old and 0% for samples 15 to 21 (0 of 11) days old. When we controlled for sample age in multivariate logistic regression, anticoagulant and storage temperature approached significance (P = 0.070 and 0.087, respectively; samples in acid citrate dextrose (ACD) and refrigerated samples were more likely to transform). Based on these findings, we suggest that samples collected in either ACD or ethylene diamine tetraacetic acid, and up to 14 days old (refrigerated) or 7 days old (stored ambient), are reasonable candidates for EBV transformation. The transformation rate for samples that met these criteria was 63% (10 of 16). Implementation of this process could help alleviate the shortage of positive control materials for clinical molecular genetic testing.