Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UMLS:C0019158 (
hepatitis
)
30,205
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Non-A non-B hepatitis is caused by an unknown infectious agent or agents, and can be transmitted by blood or products derived from blood. Laboratory and clinical data demonstrate that procedures which inactivate the AIDS virus are not sufficient to prevent non-A non-B
hepatitis
transmission. The possibility is suggested that at least one of the putative non-A non-B
hepatitis
agents might be a unique infectious agent such as a
prion
.
...
PMID:Agents causing non-A non-B hepatitis: could one be a prion? 310 35
A genetic basis for interindividual variation in susceptibility to human infectious diseases has been indicated by twin, adoptee, pedigree, and candidate gene studies. This has led to the identification of a small number of strong genetic associations with common variants for malaria, HIV infection, and infectious
prion
diseases. Numerous other genes have shown less strong associations with these and some other infectious diseases, such as tuberculosis, leprosy, and persistent
hepatitis
viral infections. Many immunogenetic loci influence susceptibility to several infectious pathogens. Recent genetic linkage analyses of measures of infection as well as of infectious disease, including some genome-wide scans, have found convincing evidence of genetic linkage to chromosomal regions wherein susceptibility genes have yet to be identified. These studies indicate a highly polygenic basis for susceptibility to many common infectious diseases, with some emerging examples of interaction between variants of specific polymorphic host and pathogen genes.
...
PMID:The genomics and genetics of human infectious disease susceptibility. 1170 55
Conformational diseases such as amyloidosis, Alzheimer's disease,
prion
diseases, and the serpinopathies are all caused by structural rearrangements within a protein that transform it into a pathological species. These diseases are typified by the Z variant of alpha(1)-antitrypsin (E342K), which causes the retention of protein within hepatocytes as inclusion bodies that are associated with neonatal
hepatitis
and cirrhosis. The inclusion bodies result from the Z mutation perturbing the conformation of the protein, which facilitates a sequential interaction between the reactive center loop of one molecule and beta-sheet A of a second. Therapies to prevent liver disease must block this reactive loop-beta-sheet polymerization without interfering with other proteins of similar tertiary structure. We have used reactive loop peptides to explore the differences between the pathogenic Z and normal M alpha(1)-antitrypsin. The results show that the reactive loop is likely to be partially inserted into beta-sheet A in Z alpha(1)-antitrypsin. This conformational difference from M alpha(1)-antitrypsin was exploited with a 6-mer reactive loop peptide (FLEAIG) that selectively and stably bound Z alpha(1)-antitrypsin. The importance of this finding is that the peptide prevented the polymerization of Z alpha(1)-antitrypsin and did not significantly anneal to other proteins (such as antithrombin, alpha(1)-antichymotrypsin, and plasminogen activator inhibitor-1) with a similar tertiary structure. These findings provide a lead compound for the development of small molecule inhibitors that can be used to treat patients with Z alpha(1)-antitrypsin deficiency. Furthermore they demonstrate how a conformational disease process can be selectively inhibited with a small peptide.
...
PMID:6-mer peptide selectively anneals to a pathogenic serpin conformation and blocks polymerization. Implications for the prevention of Z alpha(1)-antitrypsin-related cirrhosis. 1177 44
Human plasma-derived proteins, such as immunoglobulins, coagulation factors, alpha1-antitrypsin, fibrin sealants, and albumin, are widely used as therapeutics for many serious and life-threatening medical conditions. The human origin of these proteins ensures excellent efficacy and compatibility but may also introduce the risk of unintentional disease transmission. Historically, only viruses, particularly
hepatitis
and HIV, have posed serious threats to the safety of these therapeutics. Fortunately, between 1970 and 1990, the molecular biology of each of the major viruses was elucidated. These advances led to the development and implementation of effective donor screening tests, mainly based on immunoassays and nucleic acid testing, which resulted in a significant reduction of disease transmission risk. In addition, viral inactivation and removal steps were implemented and validated by manufacturers, further reducing the risk associated with known, as well as unidentified, viruses. Since the late 1990s, a different class of transmissible agent, referred to as prions, has been identified as a new risk for disease transmission. However,
prion
diseases are very rare, and
prion
transmission through plasma-derived proteins has not been reported to date. The
prion
-related risk is minimized by deferring donors with certain key risk factors, and by the manufacturing processes that are capable of removing prions. Advances in science and pathogen safety-related technology, compliance with good manufacturing practices by manufacturers, and increasingly stringent regulatory oversight, has meant that plasma-derived proteins have been developed into today's highly effective therapeutics with very low risk of disease transmission.
...
PMID:Ensuring the biologic safety of plasma-derived therapeutic proteins: detection, inactivation, and removal of pathogens. 1580 28
While transfusion of blood components is usually safe, there are risks of adverse effects that can have immunologic, nonimmunologic, or infectious causes. In patients, the fear of infectious disease transmission predominates, although the risk has been extremely low since the introduction of reliable serologic and molecular biological testing methods. This article addresses the incidence, clinical picture, and etiology of adverse effects of transfusion. It also reports on current knowledge concerning transfusion-associated acute lung injury, which has gained much attention in the last few years. Besides
hepatitis
and human immunodeficiency viruses, cytomegalovirus, parvovirus B19,
prion
transmission, and the risk of variant Creutzfeld-Jakob disease are also discussed.
...
PMID:[Risks and side effects of blood transfusion]. 1975 92
Pathogen safety is crucial for plasma-derived clotting factor concentrates used in the treatment of bleeding disorders. Plasma, the starting material for these products, is collected by plasmapheresis (source plasma) or derived from whole blood donations (recovered plasma). The primary measures regarding pathogen safety are selection of healthy donors donating in centers with appropriate epidemiologic data for the main blood-transmissible viruses, screening donations for the absence of relevant infectious blood-borne viruses, and release of plasma pools for further processing only if they are nonreactive for serologic markers and nucleic acids for these viruses. Despite this testing, pathogen inactivation and/or removal during the manufacturing process of plasma-derived clotting factor concentrates is required to ensure prevention of transmission of infectious agents. Historically,
hepatitis
viruses and human immunodeficiency virus have posed the greatest threat to patients receiving plasma-derived therapy for treatment of hemophilia or von Willebrand disease. Over the past 30 years, dedicated virus inactivation and removal steps have been integrated into factor concentrate production processes, essentially eliminating transmission of these viruses. Manufacturing steps used in the purification of factor concentrates have also proved to be successful in reducing potential
prion
infectivity. In this review, current techniques for inactivation and removal of pathogens from factor concentrates are discussed. Ideally, production processes should involve a combination of complementary steps for pathogen inactivation and/or removal to ensure product safety. Finally, potential batch-to-batch contamination is avoided by stringent cleaning and sanitization methods as part of the manufacturing process.
...
PMID:Pathogen inactivation and removal methods for plasma-derived clotting factor concentrates. 2411 99
