Metallic silver fragments cause massive tissue loss in the mouse brain.

Silver is a metal with well-known antibacterial effects. This makes silver an attractive coating material for medical devices for use inside the body, e.g. orthopaedic prostheses and catheters used in neurosurgery as it has been found to reduce the high risk of infections. Lately, the use of nano-silver particles in the industry, e.g. woven into fabrics and furniture has increased, and thus the exposure to silver particles in daily life increases. To study the effect of metallic silver particles on nervous tissue, we injected micron-sized silver particles into the mouse brain by stereotactic procedures. After 7, 14 days and 9 months, the silver-exposed animals had considerable brain damage seen as cavity formation and inflammation adjacent to the injected metallic silver particles. The tissue loss involved both cortical and hippocampal structures and resulted in enlargement of the lateral ventricles. Autometallographic silver enhancement showed silver uptake in lysosomes of glia cells and neurons in the ipsilateral cortex and hippocampus alongside a minor uptake on the contralateral side. Silver was also detected in ependymal cells and the choroid plexus. After 9 months, spreading of silver to the kidneys was seen. Cell counts of immunostained sections showed that metallic silver induced a statistically significant inflammatory response, i.e. increased microgliosis (7 days: p < 0.0001; 14 days: p < 0.01; 9 months: p < 0.0001) and TNF-α expression (7 and 14 days: p < 0.0001; 9 months: p = 0.91). Significant astrogliosis (7, 14 days and 9 months: p < 0.0001) and increased metallothionein (MT I + II) expression (7 and 14 days: p < 0.0001; 9 months: p < 0.001) were also seen in silver-exposed brain tissue. We conclude that metallic silver implants release silver ions causing neuroinflammation and a progressive tissue loss in the brain.

Metallothionein-I + II and receptor megalin are altered in relation to oxidative stress in cerebral lymphomas.

Primary central nervous system lymphoma (PCNSL) in immunocompetent patients is highly malignant and has a poor prognosis. The PCNSL molecular features are reminiscent to some degree of diffuse large B-cell lymphoma (DLBCL), yet PCNSL shows unique molecular profiles and a distinct clinical behavior. This article characterizes the histopathology and expression profiles of metallothionein-I + II (MT-I + II) and their receptor megalin along with proliferation, oxidative stress, and apoptosis in PCNSL and in central nervous system (CNS) lymphomas due to relapse from DLBCL (collectively referred to as CNS lymphoma). We show for the first time that MT-I + II and megalin are significantly altered in CNS lymphoma relative to controls (reactive lymph nodes and non-lymphoma brain tissue with neuropathology). MT-I + II are secreted in the CNS and are found mainly in the lymphomatous cells, while their receptor megalin is increased in cerebral cells. This morphology likely reflects the CNS lymphoma microenvironment and molecular interactions between lymphomatous and neuronal cells.

Metallothionein-I+II in neuroprotection.

Metallothionein (MT)-I+II synthesis is induced in the central nervous system (CNS) in response to practically any pathogen or disorder, where it is increased mainly in reactive glia. MT-I+II are involved in host defence reactions and neuroprotection during neuropathological conditions, in which MT-I+II decrease inflammation and secondary tissue damage (oxidative stress, neurodegeneration, and apoptosis) and promote post-injury repair and regeneration (angiogenesis, neurogenesis, neuronal sprouting and tissue remodelling). Intracellularly the molecular MT-I+II actions involve metal ion control and scavenging of reactive oxygen species (ROS) leading to cellular redox control. By regulating metal ions, MT-I+II can control metal-containing transcription factors, zinc-finger proteins and p53. However, the neuroprotective functions of MT-I+II also involve an extracellular component. MT-I+II protects the neurons by signal transduction through the low-density lipoprotein family of receptors on the cell surface involving lipoprotein receptor-1 (LRP1) and megalin (LRP2). In this review we discuss the newest data on cerebral MT-I+II functions following brain injury and experimental autoimmune encephalomyelitis.

Cell death in the injured brain: roles of metallothioneins.

In traumatic brain injury (TBI), the primary, irreversible damage associated with the moment of impact consists of cells dying from necrosis. This contributes to fuelling a chronic central nervous system (CNS) inflammation with increased formation of proinflammatory cytokines, enzymes and reactive oxygen species (ROS). ROS promote oxidative stress, which leads to neurodegeneration and ultimately results in programmed cell death (secondary injury). Since this delayed, secondary tissue loss occurs days to months following the primary injury it provides a therapeutic window where potential neuroprotective treatment could alleviate ongoing neurodegeneration, cell death and neurological impairment following TBI. Various neuroprotective drug candidates have been described, tested and proven effective in pre-clinical studies, including glutamate receptor antagonists, calcium-channel blockers, and caspase inhibitors. However, most of the scientific efforts have failed in translating the experimental results into clinical trials. Despite intensive research, effective neuroprotective therapies are lacking in the clinic, and TBI continues to be a major cause of morbidity and mortality. This paper provides an overview of the TBI pathophysiology leading to cell death and neurological impairment. We also discuss endogenously expressed neuroprotectants and drug candidates, which at this stage may still hold the potential for treating brain injured patients.

The role of metallothionein in oncogenesis and cancer prognosis.

The antiapoptotic, antioxidant, proliferative, and angiogenic effects of metallothionein (MT)-I+II has resulted in increased focus on their role in oncogenesis, tumor progression, therapy response, and patient prognosis. Studies have reported increased expression of MT-I+II mRNA and protein in various human cancers; such as breast, kidney, lung, nasopharynx, ovary, prostate, salivary gland, testes, urinary bladder, cervical, endometrial, skin carcinoma, melanoma, acute lymphoblastic leukemia (ALL), and pancreatic cancers, where MT-I+II expression is sometimes correlated to higher tumor grade/stage, chemotherapy/radiation resistance, and poor prognosis. However, MT-I+II are downregulated in other types of tumors (e.g. hepatocellular, gastric, colorectal, central nervous system (CNS), and thyroid cancers) where MT-I+II is either inversely correlated or unrelated to mortality. Large discrepancies exist between different tumor types, and no distinct and reliable association exists between MT-I+II expression in tumor tissues and prognosis and therapy resistance. Furthermore, a parallel has been drawn between MT-I+II expression as a potential marker for prognosis, and MT-I+II's role as oncogenic factors, without any direct evidence supporting such a parallel. This review aims at discussing the role of MT-I+II both as a prognostic marker for survival and therapy response, as well as for the hypothesized role of MT-I+II as causal oncogenes.