1H-NMR-based metabolomics to dissect the traditional Chinese medicine promotes mesenchymal stem cell homing as intervention in liver fibrosis in mouse model of Wilson's disease.

BACKGROUND: We administered Bushen Huoxue Huazhuo Formula (BSHXHZF) and transplanted bone marrow mesenchymal stem cells (BMSCs) into mice with Wilson's disease (WD)-related liver fibrosis to evaluate the liver-protecting mechanism of this prescription. METHODS: Mice, randomly divided into different treatment groups, showed histopathological changes and degree of hepatocyte apoptosis. For hepatic hydroxyproline (Hyp) determination, transforming growth factor-ß1 (TGF-ß1) and bone morphogenetic protein-7 (BMP-7) mRNA and protein were measured. Chemical profiling of the extract of BSHXHZF using The liquid chromatography-mass spectrometry (LC-MS/MS) and revealing its antifibrosis mechanism using metabolomics. RESULTS: TCM+BMSC group livers exhibited few inflammatory cells. TUNEL revealed abundant brown apoptotic cells in model control groups, while the TCM+BMSC groups showed a significant increase in blue negative expression of liver cells. Hyp in toxic milk (TX) mice groups was significantly lower than that in model control groups (MG). Compared with MG, TGF-ß1 expression was significantly lower than all other groups, while BMP-7 expression was significantly higher. Metabolic analysis identified 20 potential biomarkers and 10 key pathways, indicating that BSHXHZF+BMSC intervention has a significant regulatory effect on metabolic disorders of these small molecule substances. CONCLUSION: BSHXHZF combined with BMSCs can inhibit liver fibrosis and hepatocyte apoptosis by improving related metabolic disorders, and achieving therapeutic effects in WD-related liver fibrosis.

Genome editing without nucleases confers proliferative advantage to edited hepatocytes and corrects Wilson disease.

Application of classic liver-directed gene replacement strategies is limited in genetic diseases characterized by liver injury due to hepatocyte proliferation, resulting in decline of therapeutic transgene expression and potential genotoxic risk. Wilson disease (WD) is a life-threatening autosomal disorder of copper homeostasis caused by pathogenic variants in copper transporter ATP7B and characterized by toxic copper accumulation, resulting in severe liver and brain diseases. Genome editing holds promise for the treatment of WD; nevertheless, to rescue copper homeostasis, ATP7B function must be restored in at least 25% of the hepatocytes, which surpasses by far genome-editing correction rates. We applied a liver-directed, nuclease-free genome editing approach, based on adeno-associated viral vector-mediated (AAV-mediated) targeted integration of a promoterless mini-ATP7B cDNA into the albumin (Alb) locus. Administration of AAV-Alb-mini-ATP7B in 2 WD mouse models resulted in extensive liver repopulation by genome-edited hepatocytes holding a proliferative advantage over nonedited ones, and ameliorated liver injury and copper metabolism. Furthermore, combination of genome editing with a copper chelator, currently used for WD treatment, achieved greater disease improvement compared with chelation therapy alone. Nuclease-free genome editing provided therapeutic efficacy and may represent a safer and longer-lasting alternative to classic gene replacement strategies for WD.

Epidemiology, treatment and burden of Wilson disease in France: A 10-year analysis of the national health insurance database.

BACKGROUND & AIMS: Wilson disease (WD) is a rare hereditary, debilitating disease that is fatal if untreated. Given its low prevalence, collecting longitudinal information on large cohorts of patients is challenging. Analysis of health insurance databases offers an approach to meet this challenge. The aim of this study was to evaluate longitudinal trends in the presentation and management of patients with WD identified in the French national health insurance database (SNDS). METHODS: This retrospective, longitudinal, observational study identified people with WD in the SNDS database through hospitalisation diagnosis codes and long-term illness status between 2009 and 2019 inclusive. For each patient, data were extracted on hospitalisations, liver transplantation, mortality, WD-specific treatments (d-penicillamine, trientine and zinc), disability status and sick leave. RESULTS: 1,928 patients with WD were identified, of whom 1,520 (78.8%) were analysed. Prevalence of WD in 2019 was estimated as 2.2 cases per 100,000. Of the 670 patients first documented between 2010 and 2019, 76.1% were hospitalised at least once for a mean duration of 4.63±10.6 days. 152 patients (10.0%) underwent liver transplantation and 205 died (13.5%). The mean age at death was 57.9 ± 23.1 years. 665 patients (43.8%) received a WD-specific treatment at least once. 167 patients (17.1%) received a government disability pension and 624 (41.1%) benefited from long-term illness status due to WD. CONCLUSIONS: Unexpectedly, less than half of patients with WD received treatment recommended in practice guidelines, which may contribute to a high disease burden in terms of hospitalisations, disability and reduced life expectancy. Improving treatment rates, building patient awareness of long-term disease impact or developing a new paradigm of treatment could make a significant contribution to reducing the disease burden.

Rare co-occurrence of multiple sclerosis and Wilson's disease - case report.

BACKGROUND: Wilson's disease is a hereditary disorder of copper metabolism resulting mainly in hepatic, neurological, and psychiatric symptoms. Multiple sclerosis (MS) is an immune-mediated demyelinating disease affecting the central nervous system (CNS). The co-occurrence of these two, although not unheard of in literature, is still considered to be very rare and can give rise to diagnostic difficulties. Also, comorbidity in MS highly influences quality of life and disease progression, which makes the timely diagnosis and treatment of these conditions essential. CASE PRESENTATION: The aim of this study is to present a patient exhibiting symptoms of both MS and Wilson's disease, as well as to conduct a detailed review of previously reported cases. The patient's neurological symptoms (sensory disorder) as well as MRI and CSF findings were characteristic for MS. The diagnosis of MS preceded that of Wilson's disease and was relatively mild in course. Currently, the patient receives cladribine as an immunomodulatory treatment after escalation from glatiramer acetate therapy. Apart from one episode of acute hepatic decompensation, during which transfusion, albumin supplementation and diuretic treatment was necessary, Wilson's disease manifested as chronic impairment of liver function. The diagnosis of Wilson's disease was established by the analysis of serum coeruloplasmin levels, histological examination and genetic findings. Continuous oral penicillamine therapy led to the slow normalization of hepatic function and significant amelioration of the patient's symptoms. Correlating with cases previously reported, the course of MS was relatively mild, and like in three out of four other known cases, the symptoms of Wilson's disease were mostly restricted to hepatic dysfunction. CONCLUSION: The case presented in our report is similar to those reported before. The co-occurrence of the two diseases seems to be more a coincidence than a sharing of common factors in their pathogenesis; however, they are considered to influence one another. Regarding rare co-occurrences such as this one, every new case is of high importance, as it enables a better evaluation and understanding of the clinical presentations that are more characteristic of these cases, thus aiding the estimation of disease course as well as possible therapeutic choices.

Can therapeutic plasma exchange be life-saving in life-threatening manganese intoxication?

We present a pediatric patient presenting with life-threatening severe neurological signs, chronic liver disease, and manganese intoxication who fully recovered from neurological signs and symptoms following chelation therapy and therapeutic plasma exchange (TPE). A 13-year-old female patient was admitted with abdominal pain. Loss of consciousness and decorticate posture (GCS;M:1,V:1,M:3) developed at the 5th hour of admission. She admitted to the intensive care unit intubated. No infectious etiology that could explain acute encephalopathy was detected. Abdominal ultrasound showed granular, heterogeneous liver parenchyma suggesting chronic hepatic disease, and TPE was administered for two days since Wilson's disease and autoimmune encephalitis could not be ruled out. Cranial MRI findings were consistent with a diagnosis of manganese intoxication. On Day 3 after admission, chelation therapy and TPE were administered based on a diagnosis of manganese intoxication. Blood manganese levels at admission, day 2, and day 5 were 46, 22, and 17.5 µg/dL (NR:4.7-18.3). Control MRI results showed reduced intracranial manganese deposition, and the patient regained full consciousness. TPE as an adjunct to chelation therapy may represent an effective therapeutic option in manganese intoxication.

Fulminant Wilson Disease in Children: Recovery After Plasma Exchange Without Transplantation.

OBJECTIVES: Since 2005, a New Wilson Index (NWI) ≥11 is used as a predictor of death without transplantation in fulminant Wilson disease (WD). Plasma exchange is advocated as a new treatment modality. METHODS: We present a patient with fulminant WD treated with plasma exchange. All published cases applying plasma exchange for fulminant WD were reviewed systematically. RESULTS: A 14-year-old girl presented with hemolysis and fulminant liver failure. She had no encephalopathy; NWI was 14. As a bridge to transplantation plasma exchange was started immediately. Complete remission was achieved with plasma exchange and later chelation therapy with D-penicillamine. She is now at 3-year transplant-free survival. Literature review identified 37 patients presenting with fulminant WD and NWI ≥11 who were treated with plasma exchange. Seventeen of these patients (ie, 46%) recovered without transplantation. CONCLUSIONS: Multiple case reports and case series demonstrate transplant free survival after plasma exchange and subsequent chelation therapy, despite a NWI ≥11. Plasma exchange affects the clinical course and is a therapeutic option in children and young adults presenting with fulminant WD.

Outcomes of Acute Liver Injury in Adults Due to Wilson's Disease: Is Survival Without Transplant Possible?

Wilson's disease (WD) is a rare cause of acute liver failure (ALF) that is thought to have a uniformly fatal outcome without liver transplantation (LT). Previous studies proposed diagnostic and prognostic criteria for WD-ALF. It is not known whether these apply to WD patients presenting as severe acute liver injury (ALI) without encephalopathy. From 2008 to 2018, 822 patients with ALI in the US Acute Liver Failure Study Group (ALFSG) registry were enrolled and prospectively followed. The diagnosis of WD-ALI was confirmed in 8 patients. Serum biochemical diagnostic ratios predicting WD-ALF (alkaline phosphatase [ALP]:total bilirubin(TB) and aspartate aminotransferase [AST]:alanine aminotransferase [ALT]) were determined in these patients, and predictors of prognosis for WD-ALI were evaluated. Of these 8 ALI-WD patients, 5 received an LT. Ratios of both ALP:TB of <4 and AST:ALT of >2.2 on study admission were met in 4 LT patients. All LT patients were female. The Model for End-Stage Liver Disease scores on admission were generally higher in LT patients. All transplanted patients had an initial revised WD score of >11 (>10 predicting poor outcome without LT in WD-ALF), whereas in non-LT patients, 2 had scores of 9, and 1 a score of 13. Also, 3 LT patients were started on chelation therapy, 2 were started on plasmapheresis, and 1 was started on Molecular Adsorbent Recirculating System therapy. All non-LT patients were treated with chelation. At 21 days, all patients were alive and discharged from the hospital. In conclusion, some patients with ALI due to WD may survive without LT. Revised Wilson index scores >10 predict poor outcome in most patients with WD-ALI, as they do for WD-ALF, and they correlate positively with the ALI model in this cohort. Biochemical ratios for WD diagnosis appear more applicable to ALF compared with WD-ALI.

The study of Wilson disease in pregnancy management.

INTRODUCTION: Pregnancy management in women with Wilson disease (WD) remains an important clinical problem. This research was conducted to investigate how to avoid worsening of WD symptoms during pregnancy and increase pregnancy success in women with WD by identifying the best pregnancy management approaches in these patients. PATIENTS AND METHODS: The clinical data of 117 pregnancies among 75 women with WD were retrospectively analyzed. Related information of the fetus was also recorded and analyzed. At the same time, regression analysis was performed for data of 22 pregnant women without WD, as normal controls. RESULTS: Of a total of 117 pregnancies among the 75 women with WD and 31 pregnancies among the 22 control womenincluded in this study, there were 108 successful pregnancies and 9 spontaneous abortions. Among the 108 successful pregnancies, 97 women a history of copper chelation therapy before pregnancy; all 97 women stopped anti-copper therapy during pregnancy. The nine women with spontaneous abortion had no pre-pregnancy history of copper displacement therapy. The incidence of lower limb edema was higher in the WD group than in normal controls (P = 0.036). Compared with the control group, there was a higher proportion in the WD group of male infants (P = 0.022) and lower average infant birth weight (t = 3.514, P = 0.001). CONCLUSION: It is relatively safe for women with WD patients to become pregnant. The best management method for pregnancy in women with WD may be intensive pre-pregnancy copper chelation therapy and no anti-copper treatment during pregnancy.

Liver Expression of a MiniATP7B Gene Results in Long-Term Restoration of Copper Homeostasis in a Wilson Disease Model in Mice.

Gene therapy with an adeno-associated vector (AAV) serotype 8 encoding the human ATPase copper-transporting beta polypeptide (ATP7B) complementary DNA (cDNA; AAV8-ATP7B) is able to provide long-term copper metabolism correction in 6-week-old male Wilson disease (WD) mice. However, the size of the genome (5.2 kilobases [kb]) surpasses the optimal packaging capacity of the vector, which resulted in low-yield production; in addition, further analyses in WD female mice and in animals with a more advanced disease revealed reduced therapeutic efficacy, as compared to younger males. To improve efficacy of the treatment, an optimized shorter AAV vector was generated, in which four out of six metal-binding domains (MBDs) were deleted from the ATP7B coding sequence, giving rise to the miniATP7B protein (Δ57-486-ATP7B). In contrast to AAV8-ATP7B, AAV8-miniATP7B could be produced at high titers and was able to restore copper homeostasis in 6- and 12-week-old male and female WD mice. In addition, a recently developed synthetic AAV vector, AAVAnc80, carrying the miniATP7B gene was similarly effective at preventing liver damage, restoring copper homeostasis, and improving survival 1 year after treatment. Transduction of approximately 20% of hepatocytes was sufficient to normalize copper homeostasis, suggesting that corrected hepatocytes are acting as a sink to eliminate excess of copper. Importantly, administration of AAVAnc80-miniATP7B was safe in healthy mice and did not result in copper deficiency. Conclusion: In summary, gene therapy using an optimized therapeutic cassette in different AAV systems provides long-term correction of copper metabolism regardless of sex or stage of disease in a clinically relevant WD mouse model. These results pave the way for the implementation of gene therapy in WD patients.

Therapeutic potential of hepatocyte-like-cells converted from stem cells from human exfoliated deciduous teeth in fulminant Wilson's disease.

Wilson's disease (WD) is an inherited metabolic disease arising from ATPase copper transporting beta gene (ATP7B) mutation. Orthotoropic liver transplantation is the only radical treatment of fulminant WD, although appropriate donors are lacking at the onset of emergency. Given the hepatogenic capacity and tissue-integration/reconstruction ability in the liver of stem cells from human exfoliated deciduous teeth (SHED), SHED have been proposed as a source for curing liver diseases. We hypothesized the therapeutic potential of SHED and SHED-converted hepatocyte-like- cells (SHED-Heps) for fulminant WD. SHED and SHED-Heps were transplanted into WD model Atp7b-mutated Long-Evans Cinnamon (LEC) rats received copper overloading to induce a lethal fulminant liver failure. Due to the superior copper tolerance via ATP7B, SHED-Hep transplantation gave more prolonged life-span of fulminant LEC rats than SHED transplantation. The integrated ATP7B-expressing SHED-Heps showed more therapeutic effects on to restoring the hepatic dysfunction and tissue damages in the recipient liver than the integrated naïve SHED without ATP7B expression. Moreover, SHED-Heps could reduce copper-induced oxidative stress via ATP7B- independent stanniocalcin 1 secretion in the fulminant LEC rats, suggesting a possible role for paracrine effect of the integrated SHED-Heps. Taken together, SHED-Heps offer a potential of functional restoring, bridging, and preventive approaches for treating fulminant WD.

A Gene Therapy Approach to Improve Copper Metabolism and Prevent Liver Damage in a Mouse Model of Wilson Disease.

Wilson disease (WD), an autosomal recessive disease caused by mutations in a copper-transporting P-type ATPase (Atp7b), causes severe liver damage. This disease is currently treated with the lifelong use of copper chelation therapy, which has side effects and does not fix copper metabolism. Here, we thoroughly characterized a mouse model of WD, the toxic milk mouse, and used the model to test a gene therapy approach for treating WD. WD mice accumulated copper in the liver from birth; severe copper accumulation and concurrent liver disease were evident by 2 months of age. Intravenously administering an adeno-associated viral (AAV) 8 vector expressing a codon-optimized version of the human ATP7B transgene into 2-month-old WD mice significantly decreased liver copper levels compared with age-matched, uninjected, WD mice. We also observed a significant dose-dependent decrease in liver disease. Male mice injected with 1011 genome copies of AAV8 vector showed only mild histopathological findings with a complete lack of liver fibrosis. Therefore, we conclude that administering gene therapy at the early stages of disease onset is a promising approach for reducing liver damage and correcting copper metabolism in WD.

Clinical Utility of Longitudinal Measurement of Motor Threshold in Wilson's Disease.

This study describes the longitudinal changes of resting motor threshold (RMT) and central motor conduction time (CMCT) in 18 patients with Wilson's disease (WD). The RMT, CMCT, and Global Assessment Scale for Wilson Disease (GAS-WD) were measured at baseline and at follow-up after 12.94 ± 7.23 months. There was a significant decrease in the RMT (72.11 ± 18.62 vs. 63.7 ± 15.52%; p-value = 0.002) and GAS-WD scores (14.38 ± 5.35 vs. 9.77 ± 6.47 ms; p-value = 0.04). CMCT did not improve despite chelation therapy. Hence, RMT may serve as a marker of chelation efficacy in WD.

Plasmapheresis Combined with Continuous Plasma Filtration Adsorption Rescues Severe Acute Liver Failure in Wilson's Disease before Liver Transplantation.

Wilsonian crisis (hemolytic crisis and acute liver failure [ALF] in Wilson's disease) is fatal and almost all patients ultimately need a timely liver transplantation to save their lives. How to safely pass the critical period to liver transplantation is still a big challenge to doctors especially to pediatricians facing more difficult situations in blood purification. Here, we report about a 7-year-old child (weight 21 kg) presenting with severe hemolysis and impending ALF that made a rapid recovery with prompt initiation of plasmapheresis combined with continuous plasma filtration adsorption (CPFA) and chelation therapy. Rapidly efficient removal of copper, bilirubin, and albumin-binding toxins by hybrid blood purification alleviated hemolysis and liver injury and successfully bridged the patient over the critical period to late liver transplantation. Moreover, a review of the literature was performed examining the use of plasmapheresis, molecular adsorbent recirculation system, single-pass albumin dialysis, and continuous veno-venous hemodiafiltration in Wilson disease. The experience of our case points to that plasmapheresis combined with CPFA treatment can improve clinical symptoms and bridge children over through Wilsonian crisis to late live transplantation, and CPFA treatment is feasible and safe in children weighing more than 20 kg.

History of Wilson disease: a personal account.

This chapter focuses on the historic aspects of the development of much of our current knowledge of the diagnosis and treatment of Wilson disease. Included are descriptions of the clinical signs of neurologic and hepatic disease, the natural history of disease progression, studies of disease pathogenesis and a unique perspective on the development of diagnostic testing and pharmacological therapy.

Inherited disorders of transition metal metabolism: an update.

Elements with a biological role include six trace transition metals: manganese, iron, cobalt, copper, zinc and molybdenum. Transition metals participate in group transfer reactions such as glycosylation and phosphorylation and those that can transfer an electron by alternating between two redox states such as iron (3+/2+) and copper (2+/1+) are also very important in biological redox reactions including the reduction of molecular oxygen and the transport of oxygen. However, these trace metals are also potentially toxic, generating reactive oxygen species through Fenton chemistry. Recently, a role of trace metals in host defence ("nutritional immunity") has been recognized. The host can deprive the pathogen of a trace metal or poison it with a toxic concentration. Disorders leading to low concentrations of a trace metal can often be treated by supplementing that metal; disorders leading to excessively high concentrations can often be treated with chelating agents such as penicillamine and disodium calcium edetate. This update will address: i) the manganese/zinc transporters (because two new treatable disorders were described in 2016 - SLC39A8 deficiency and SLC39A14 deficiency); ii) copper transporter disorders because we need to improve the treatment of patients with neurological symptoms due to Wilson's disease; and iii) iron homeostasis because recent progress in research into the metabolism of iron and its regulation helps us better understand several inborn errors affecting these pathways.

Demonstrating Potential of Cell Therapy for Wilson's Disease with the Long-Evans Cinnamon Rat Model.

Wilson's disease (WD) is characterized by the inability to excrete copper (Cu) from the body with progressive tissue injury, especially in liver and brain. The molecular defect in WD concerns mutations in ATP7B gene leading to loss of Cu transport from the hepatocyte to the bile canaliculus. While drugs, e.g., Cu chelators, have been available for several decades, these must be taken lifelong, which can be difficult due to issues of compliance or side effects. Many individuals may require liver transplantation, which can also be difficult due to donor organ shortages. Therefore, achieving permanent cures via cell or gene therapy are of great interest for WD. Cell therapy is feasible because transplanted hepatocytes can integrate in liver parenchyma and restore deficient functions, including transport of Cu into bile. The availability of authentic animal models that recapitulate hepatic WD, especially the Long-Evans Cinnamon (LEC) rat, has advanced cell transplantation research in WD. We describe requirements for cell therapy in animal models with several standardized methods for studies to test or refine cell therapy strategies in WD.

Wilson's Disease in Thai Children between 2000 and 2012 at King Chulalongkorn Memorial Hospital.

OBJECTIVE: Wilson's disease (WD) is a rare autosomal recessive disorder characterized by copper accumulation. Clinical presentations are extraordinarily diverse, and currently no single diagnostic test can confirm WD with high accuracy. A complete understanding of the presentations and improved diagnostic methods are important for disease management. The authors' aimed to examine disease characteristics, management, and treatment outcome of WD in children, especially when genetic analysis and liver copper measurements were limited. MATERIAL AND METHOD: Data was collected from 21 WD children who were treated at King Chulalongkorn Memorial Hospital between 2000 and 2012. Inclusion criteria followed the WD scoring system, where other liver diseases are ruled out systematically. RESULTS: The mean age at diagnosis was 13.5 ± 3.36 years, with 19 symptomatic patients, and two asymptomatic individuals who were diagnosed through family screening. Presentations varied, jaundice (52%), ascites (52%), edema (52%), Coombs-negative hemolytic anemia (14%), neurological abnormalities (33%), renal involvement (19%), and fulminant hepatic failure (5%). Based on the key parameters in WD scoring system, 14 patients (66%) had Kayser-Fleischer (KF) rings. Seventeen (89%) had low serum ceruloplasmin, and 20 (95%) had increased urinary copper excretion. These positive findings made WD scoring system accurately diagnose 66% of patients. Chelation therapy was the first line of therapy for all patients except one, who underwent liver transplantation. After therapy, liver function test returned to normal in all patients. However, neurological symptoms did not improve with combined drug therapy using chelating and neuropsychiatric agents. CONCLUSION: WD in children mostly affected the liver WD was suspected in seven patients (34%), thus needed further investigation. Therefore, long-term follow-up in those with suspected WD is the appropriate method for diagnosis and management in limited diagnostic tests. We suggest further treatment, and use of clinical response to treatment, as a criterion for confirming the WD diagnosis.

Canine Models for Copper Homeostasis Disorders.

Copper is an essential trace nutrient metal involved in a multitude of cellular processes. Hereditary defects in copper metabolism result in disorders with a severe clinical course such as Wilson disease and Menkes disease. In Wilson disease, copper accumulation leads to liver cirrhosis and neurological impairments. A lack in genotype-phenotype correlation in Wilson disease points toward the influence of environmental factors or modifying genes. In a number of Non-Wilsonian forms of copper metabolism, the underlying genetic defects remain elusive. Several pure bred dog populations are affected with copper-associated hepatitis showing similarities to human copper metabolism disorders. Gene-mapping studies in these populations offer the opportunity to discover new genes involved in copper metabolism. Furthermore, due to the relatively large body size and long life-span of dogs they are excellent models for development of new treatment strategies. One example is the recent use of canine organoids for disease modeling and gene therapy of copper storage disease. This review addresses the opportunities offered by canine genetics for discovery of genes involved in copper metabolism disorders. Further, possibilities for the use of dogs in development of new treatment modalities for copper storage disorders, including gene repair in patient-derived hepatic organoids, are highlighted.