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1.
HRB Open Res ; 4: 96, 2021.
Article in English | MEDLINE | ID: mdl-35280850

ABSTRACT

Biobanks are repositories of human biological samples and data. They are an important component of clinical research in many disease areas and often represent the first step toward innovative treatments. For biobanks to operate, researchers need human participants to give their samples and associated health data. In Ireland, research participants must provide their freely given informed consent for their samples and data to be taken and used for research purposes. Biobank staff are responsible for communicating the relevant information to participants prior to obtaining their consent, and this communication process is supported by documentation in the form of Participant Information Leaflets and Informed Consent Forms (PILs/ICFs). PILs/ICFs should be concise, intelligible, and contain relevant information. While not a substitute for layperson and research staff discussions, PILs and ICFs ensure that a layperson has enough information to make an informed choice to participate or not. However, PILs/ICFs are often lengthy, contain technical language and can be complicated and onerous for a layperson to read. The introduction of the General Data Protection Regulation (GDPR) and the related Irish Health Research Regulation (HRR) presented additional challenges to the Irish biobank community. In May 2019, the National Biobanking Working Group (NBWG) was established in Ireland. It consists of members from diverse research backgrounds located in universities, hospitals and research centres across Ireland and a public/patient partner. The NBWG aimed to develop a suite of resources for health research biobanks via robust and meaningful patient engagement, which are accessible, GDPR/HRR-compliant and could be used nationally, including a PIL/ICF template. This open letter describes the process whereby this national biobank PIL/ICF template was produced. The development of this template included review by the Patient Voice in Cancer Research, led by Professor Amanda McCann at University College Dublin and the Health Research Data Protection Network.

2.
Ir J Med Sci ; 190(2): 505-514, 2021 May.
Article in English | MEDLINE | ID: mdl-32728834

ABSTRACT

BACKGROUND: Irish Health Research Regulations (HRRs) were introduced following the European Union (EU) General Data Protection Regulation (GDPR) in 2018. The HRRs described specific supplementary regulatory requirements for research regarding governance, processes and procedure that impact on several facets of research. The numerous problems that the HRRs and particularly "explicit consent" inadvertently created were presented under the auspices of the Irish Academy of Medical Sciences (IAMS) on November 25, 2019, at the Royal College of Surgeons in Ireland. AIMS: The objective of this review was to obtain feedback and to examine the impact of GDPR and the HRRs on health research in Ireland in order to determine whether the preliminary feedback, presented at the IAMS meetings, was reflected at a national level. METHODS: Individuals from the research community were invited to provide feedback on the impact, if any, of the HRRs on health research. Retrospective patient recruitment and consent outside a hospital setting for a multi-institutional Breast Predict study (funded by the Irish Cancer Society) were also analysed. RESULTS: Feedback replicated the issues presented at the IAMS with additional concerns identified. Only 20% of the original target population (n = 1987) could be included in the Breast Predict study. CONCLUSIONS: Our results confirm that the HRRs have had a significantly negative impact on health research in Ireland. Urgent meaningful engagement between patient advocate groups, the research community and legislators would help ameliorate these impacts.


Subject(s)
Biomedical Research/legislation & jurisprudence , Computer Security/legislation & jurisprudence , Government Regulation , Research Design/legislation & jurisprudence , Female , Humans , Ireland , Male , Retrospective Studies
3.
Ir J Med Sci ; 190(2): 515-521, 2021 May.
Article in English | MEDLINE | ID: mdl-32728835

ABSTRACT

BACKGROUND: Irish Health Research Regulations (HRRs) were introduced following the commencement of the General Data Protection Regulation (GDPR) in 2018. The HRRs set out supplementary regulatory requirements for research. A legal analysis presented under the auspices of the Irish Academy of Medical Sciences (IAMS) on April 8 and November 25, 2019 at the Royal College of Surgeons in Ireland welcomed the introduction of GDPR and the HRRs. The analysis found the GDPR "explicit consent" introduced by the HRRs is problematic. A call was made to regulate informed consent in line with the common law as an achievable alternative safeguard, bringing Ireland in line with other EU Member States. AIMS: This article aims to review academic papers, legal opinion, EU opinion and advice and data protection law in relation to research and explicit consent, in order to examine the legal burden of GDPR and the HRRs on health research in Ireland and to determine whether the analysis presented at the IAMS meetings is reflected more widely in legal text. METHODS: Legal literature review of academic papers, legal opinion, EU opinion and advice and data protection legislation. RESULTS: The legal literature review overwhelmingly supports the concerns raised. CONCLUSIONS: Our results confirm the GDPR explicit consent requirement of the HRRs is having had a significantly negative and far-reaching impact on the conduct of health research in Ireland. Urgent review of the HRRs and meaningful engagement between the health research community and legislators in healthcare is required.


Subject(s)
Biomedical Research/legislation & jurisprudence , Computer Security/legislation & jurisprudence , Government Regulation , Informed Consent/legislation & jurisprudence , Research Design/legislation & jurisprudence , Female , Humans , Ireland , Male
4.
FEBS J ; 275(12): 3041-50, 2008 Jun.
Article in English | MEDLINE | ID: mdl-18445038

ABSTRACT

Pyridine-linked oxidoreductase enzymes of Helicobacter pylori have been implicated in the pathogenesis of gastric disease. Previous studies in this laboratory examined a cinnamyl alcohol dehydrogenase that was capable of detoxifying a range of aromatic aldehydes. In the present work, we have extended these studies to identify and characterize an aldoketo reductase (AKR) enzyme present in H. pylori. The gene encoding this AKR was identified in the sequenced strain of H. pylori, 26695. The gene, referred to as HpAKR, was cloned and expressed in Escherichia coli as a His-tag fusion protein, and purified using nickel chelate chromatography. The gene product (HpAKR) has been assigned to the AKR13C1 family, although it differs in specificity from the two other known members of this family. The enzyme is a monomer with a molecular mass of approximately 39 kDa on SDS/PAGE. It reduces a range of aromatic aldehyde substrates with high catalytic efficiency, and exhibits dual cofactor specificity for both NADPH and NADH. HpAKR can function over a broad pH range (pH 4-9), and has a pH optimum of 5.5. It is inhibited by sodium valproate. Its substrate specificity complements that of the cinnamyl alcohol dehydrogenase activity in H. pylori, giving the organism the capacity to reduce a wide range of aldehydes. Generation of an HpAKR isogenic mutant of H. pylori demonstrated that HpAKR is required for growth under acidic conditions, suggesting an important role for this enzyme in adaptation to growth in the gastric mucosa. This AKR is a member of a hitherto little-studied class.


Subject(s)
Alcohol Oxidoreductases/chemistry , Bacterial Proteins/chemistry , Helicobacter pylori/enzymology , Adaptation, Physiological , Alcohol Oxidoreductases/genetics , Aldehyde Reductase , Aldo-Keto Reductases , Bacterial Proteins/genetics , Catalysis , Enzyme Stability , Helicobacter pylori/growth & development , Hydrogen-Ion Concentration , Mutagenesis, Insertional , Recombinant Proteins/metabolism , Sequence Alignment , Sequence Analysis, Protein , Substrate Specificity
5.
FEBS J ; 272(5): 1255-64, 2005 Mar.
Article in English | MEDLINE | ID: mdl-15720399

ABSTRACT

Cinnamyl alcohol dehydrogenases (CAD; 1.1.1.195) catalyse the reversible conversion of p-hydroxycinnamaldehydes to their corresponding alcohols, leading to the biosynthesis of lignin in plants. Outside of plants their role is less defined. The gene for cinnamyl alcohol dehydrogenase from Helicobacter pylori (HpCAD) was cloned in Escherichia coli and the recombinant enzyme characterized for substrate specificity. The enzyme is a monomer of 42.5 kDa found predominantly in the cytosol of the bacterium. It is specific for NADP(H) as cofactor and has a broad substrate specificity for alcohol and aldehyde substrates. Its substrate specificity is similar to the well-characterized plant enzymes. High substrate inhibition was observed and a mechanism of competitive inhibition proposed. The enzyme was found to be capable of catalysing the dismutation of benzaldehyde to benzyl alcohol and benzoic acid. This dismutation reaction has not been shown previously for this class of alcohol dehydrogenase and provides the bacterium with a means of reducing aldehyde concentration within the cell.


Subject(s)
Alcohol Oxidoreductases/metabolism , Benzaldehydes/metabolism , Helicobacter pylori/enzymology , Alcohol Oxidoreductases/chemistry , Benzaldehydes/chemistry , Benzyl Alcohol/chemistry , Benzyl Alcohol/metabolism , Catalysis , Cloning, Molecular , Kinetics , NADP , Recombinant Proteins/chemistry , Recombinant Proteins/metabolism , Subcellular Fractions , Substrate Specificity
6.
Biopreserv Biobank ; 11(1): 3-11, 2013 Feb.
Article in English | MEDLINE | ID: mdl-24845249

ABSTRACT

Biobank Ireland Trust (BIT) was established in 2004 to promote and develop an Irish biobank network to benefit patients, researchers, industry, and the economy. The network commenced in 2008 with two hospital biobanks and currently consists of biobanks in the four main cancer hospitals in Ireland. The St. James's Hospital (SJH) Biobank coordinates the network. Procedures, based on ISBER and NCI guidelines, are standardized across the network. Policies and documents-Patient Consent Policy, Patient Information Sheet, Biobank Consent Form, Sample and Data Access Policy (SAP), and Sample Application Form have been agreed upon (after robust discussion) for use in each hospital. An optimum sequence for document preparation and submission for review is outlined. Once consensus is reached among the participating biobanks, the SJH biobank liaises with the Research and Ethics Committees, the Office of the Data Protection Commissioner, The National Cancer Registry (NCR), patient advocate groups, researchers, and other stakeholders. The NCR provides de-identified data from its database for researchers via unique biobank codes. ELSI issues discussed include the introduction of prospective consent across the network and the return of significant research results to patients. Only 4 of 363 patients opted to be re-contacted and re-consented on each occasion that their samples are included in a new project. It was decided, after multidisciplinary discussion, that results will not be returned to patients. The SAP is modeled on those of several international networks. Biobank Ireland is affiliated with international biobanking groups-Marble Arch International Working Group, ISBER, and ESBB. The Irish government continues to deliberate on how to fund and implement biobanking nationally. Meanwhile BIT uses every opportunity to promote awareness of the benefits of biobanking in events and in the media.


Subject(s)
Biological Specimen Banks/organization & administration , Biological Specimen Banks/ethics , Biomedical Research/ethics , Documentation/standards , Humans , Information Storage and Retrieval/ethics , Internationality , Ireland , Neoplasms/pathology , Registries
7.
Biopreserv Biobank ; 9(4): 389-398, 2011 Dec.
Article in English | MEDLINE | ID: mdl-23386926

ABSTRACT

The Saint James's Hospital Biobank was established in 2008, to develop a high-quality breast tissue BioResource, as a part of the breast cancer clinical care pathway. The aims of this work were: (1) to ascertain the quality of RNA, DNA, and protein in biobanked carcinomas and normal breast tissues, (2) to assess the efficacy of AllPrep(®) (Qiagen) in isolating RNA, DNA, and protein simultaneously, (3) to compare AllPrep with RNEasy(®) and QIAamp(®) (both Qiagen), and (4) to examine the effectiveness of Allprotect(®) (Qiagen), a new tissue stabilization medium in preserving DNA, RNA, and proteins. One hundred eleven frozen samples of carcinoma and normal breast tissue were analyzed. Tumor and normal tissue morphology were confirmed by frozen sections. Tissue type, tissue treatment (Allprotect vs. no Allprotect), extraction kit, and nucleic acid quantification were analyzed by utilizing a 4 factorial design (SPSS PASW 18 Statistics Software(®)). QIAamp (DNA isolation), AllPrep (DNA, RNA, and Protein isolation), and RNeasy (RNA isolation) kits were assessed and compared. Mean DNA yield and A(260/280) values using QIAamp were 33.2 ng/µL and 1.86, respectively, and using AllPrep were 23.2 ng/µL and 1.94. Mean RNA yield and RNA Integrity Number (RIN) values with RNeasy were 73.4 ng/µL and 8.16, respectively, and with AllPrep were 74.8 ng/µL and 7.92. Allprotect-treated tissues produced higher RIN values of borderline significance (P=0.055). No discernible loss of RNA stability was detected after 6 h incubation of stabilized or nonstabilized tissues at room temperature or 4°C or in 9 freeze-thaw cycles. Allprotect requires further detailed evaluation, but we consider AllPrep to be an excellent option for the simultaneous extraction of RNA, DNA, and protein from tumor and normal breast tissues. The essential presampling procedures that maintain the diagnostic integrity of pathology specimens do not appear to compromise the quality of molecular isolates.

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