Friday, January 30, 2015

Scrapie: a particularly persistent pathogen

98 | Veterinary Record | January 24, 2015

 

EDITORIAL

 

Scrapie: a particularly persistent pathogen

 

Cristina Acín

 

Resistant prions in the environment have been the sword of Damocles for scrapie control and eradication. Attempts to establish which physical and chemical agents could be applied to inactivate or moderate scrapie infectivity were initiated in the 1960s and 1970s,with the first study of this type focusing on the effect of heat treatment in reducing prion infectivity (Hunter and Millson 1964). Nowadays, most of the chemical procedures that aim to inactivate the prion protein are based on the method developed by Kimberlin and collaborators (1983). This procedure consists of treatment with 20,000 parts per million free chlorine solution, for a minimum of one hour, of all surfaces that need to be sterilised (in laboratories, lambing pens, slaughterhouses, and so on). Despite this, veterinarians and farmers may still ask a range of questions, such as ‘Is there an official procedure published somewhere?’ and ‘Is there an international organisation which recommends and defines the exact method of scrapie decontamination that must be applied?’

 

From a European perspective, it is difficult to find a treatment that could be applied, especially in relation to the disinfection of surfaces in lambing pens of affected flocks. A 999/2001 EU regulation on controlling spongiform encephalopathies (European Parliament and Council 2001) did not specify a particular decontamination measure to be used when an outbreak of scrapie is diagnosed. There is only a brief recommendation in Annex VII concerning the control and eradication of transmissible spongiform encephalopathies (TSE s).

 

Chapter B of the regulation explains the measures that must be applied if new caprine animals are to be introduced to a holding where a scrapie outbreak has previously been diagnosed. In that case, the statement indicates that caprine animals can be introduced ‘provided that a cleaning and disinfection of all animal housing on the premises has been carried out following destocking’.

 

Issues around cleaning and disinfection are common in prion prevention recommendations, but relevant authorities, veterinarians and farmers may have difficulties in finding the specific protocol which applies. The European Food and Safety Authority (EFSA ) published a detailed report about the efficacy of certain biocides, such as sodium hydroxide, sodium hypochlorite, guanidine and even a formulation of copper or iron metal ions in combination with hydrogen peroxide, against prions (EFSA 2009). The report was based on scientific evidence (Fichet and others 2004, Lemmer and others 2004, Gao and others 2006, Solassol and others 2006) but unfortunately the decontamination measures were not assessed under outbreak conditions.

 

The EFSA Panel on Biological Hazards recently published its conclusions on the scrapie situation in the EU after 10 years of monitoring and control of the disease in sheep and goats (EFSA 2014), and one of the most interesting findings was the Icelandic experience regarding the effect of disinfection in scrapie control. The Icelandic plan consisted of: culling scrapie-affected sheep or the whole flock in newly diagnosed outbreaks; deep cleaning and disinfection of stables, sheds, barns and equipment with high pressure washing followed by cleaning with 500 parts per million of hypochlorite; drying and treatment with 300 ppm of iodophor; and restocking was not permitted for at least two years. Even when all of these measures were implemented, scrapie recurred on several farms, indicating that the infectious agent survived for years in the environment, even as many as 16 years after restocking (Georgsson and others 2006).

 

In the rest of the countries considered in the EFSA (2014) report, recommendations for disinfection measures were not specifically defined at the government level. In the report, the only recommendation that is made for sheep is repopulation with sheep with scrapie-resistant genotypes. This reduces the risk of scrapie recurrence but it is difficult to know its effect on the infection.

 

Until the EFSA was established (in May 2003), scientific opinions about TSE s were provided by the Scientific Steering Committee (SSC) of the EC, whose advice regarding inactivation procedures focused on treating animal waste at high temperatures (150°C for three hours) and high pressure alkaline hydrolysis (SSC 2003). At the same time, the TSE Risk Management Subgroup of the Advisory Committee on Dangerous Pathogens (ACDP) in the UK published guidance on safe working and the prevention of TSE infection. Annex C of the ACDP report established that sodium hypochlorite was considered to be effective, but only if 20,000 ppm of available chlorine was present for at least one hour, which has practical limitations such as the release of chlorine gas, corrosion, incompatibility with formaldehyde, alcohols and acids, rapid inactivation of its active chemicals and the stability of dilutions (ACDP 2009).

 

In an international context, the World Organisation for Animal Health (OIE) does not recommend a specific disinfection protocol for prion agents in its Terrestrial Code or Manual. Chapter 4.13 of the Terrestrial Code, General recommendations on disinfection and disinsection (OIE 2014), focuses on foot-and-mouth disease virus, mycobacteria and Bacillus anthracis, but not on prion disinfection. Nevertheless, the last update published by the OIE on bovine spongiform encephalopathy (OIE 2012) indicates that few effective decontamination techniques are available to inactivate the agent on surfaces, and recommends the removal of all organic material and the use of sodium hydroxide, or a sodium hypochlorite solution containing 2 per cent available chlorine, for more than one hour at 20ºC.

 

The World Health Organization outlines guidelines for the control of TSE s, and also emphasises the importance of mechanically cleaning surfaces before disinfection with sodium hydroxide or sodium hypochlorite for one hour (WHO 1999).

 

Finally, the relevant agencies in both Canada and the USA suggest that the best treatments for surfaces potentially contaminated with prions are sodium hydroxide or sodium hypochlorite at 20,000 ppm. This is a 2 per cent solution, while most commercial household bleaches contain 5.25 per cent sodium hypochlorite. It is therefore recommended to dilute one part 5.25 per cent bleach with 1.5 parts water (CDC 2009, Canadian Food Inspection Agency 2013).

 

So what should we do about disinfection against prions? First, it is suggested that a single protocol be created by international authorities to homogenise inactivation procedures and enable their application in all scrapie-affected countries. Sodium hypochlorite with 20,000 ppm of available chlorine seems to be the procedure used in most countries, as noted in a paper summarised on p 99 of this issue of Veterinary Record (Hawkins and others 2015). But are we totally sure of its effectiveness as a preventive measure in a scrapie outbreak? Would an in-depth study of the recurrence of scrapie disease be needed?

 

What we can conclude is that, if we want to fight prion diseases, and specifically classical scrapie, we must focus on the accuracy of diagnosis, monitoring and surveillance; appropriate animal identification and control of movements; and, in the end, have homogeneous and suitable protocols to decontaminate and disinfect lambing barns, sheds and equipment available to veterinarians and farmers. Finally, further investigations into the resistance of prion proteins in the diversity of environmental surfaces are required.

 

References

 

snip...

 

98 | Veterinary Record | January 24, 2015

 


 

Persistence of ovine scrapie infectivity in a farm environment following cleaning and decontamination

 

Steve A. C. Hawkins, MIBiol, Pathology Department1, Hugh A. Simmons, BVSc MRCVS, MBA, MA Animal Services Unit1, Kevin C. Gough, BSc, PhD2 and Ben C. Maddison, BSc, PhD3 + Author Affiliations

 

1Animal and Plant Health Agency, Woodham Lane, New Haw, Addlestone, Surrey KT15 3NB, UK 2School of Veterinary Medicine and Science, The University of Nottingham, Sutton Bonington, Loughborough, Leicestershire LE12 5RD, UK 3ADAS UK, School of Veterinary Medicine and Science, The University of Nottingham, Sutton Bonington, Loughborough, Leicestershire LE12 5RD, UK E-mail for correspondence: ben.maddison@adas.co.uk Abstract Scrapie of sheep/goats and chronic wasting disease of deer/elk are contagious prion diseases where environmental reservoirs are directly implicated in the transmission of disease. In this study, the effectiveness of recommended scrapie farm decontamination regimens was evaluated by a sheep bioassay using buildings naturally contaminated with scrapie. Pens within a farm building were treated with either 20,000 parts per million free chorine solution for one hour or were treated with the same but were followed by painting and full re-galvanisation or replacement of metalwork within the pen. Scrapie susceptible lambs of the PRNP genotype VRQ/VRQ were reared within these pens and their scrapie status was monitored by recto-anal mucosa-associated lymphoid tissue. All animals became infected over an 18-month period, even in the pen that had been subject to the most stringent decontamination process. These data suggest that recommended current guidelines for the decontamination of farm buildings following outbreaks of scrapie do little to reduce the titre of infectious scrapie material and that environmental recontamination could also be an issue associated with these premises.

 

SNIP...

 

Discussion

 

Thorough pressure washing of a pen had no effect on the amount of bioavailable scrapie infectivity (pen B). The routine removal of prions from surfaces within a laboratory setting is treatment for a minimum of one hour with 20,000 ppm free chlorine, a method originally based on the use of brain macerates from infected rodents to evaluate the effectiveness of decontamination (Kimberlin and others 1983). Further studies have also investigated the effectiveness of hypochlorite disinfection of metal surfaces to simulate the decontamination of surgical devices within a hospital setting. Such treatments with hypochlorite solution were able to reduce infectivity by 5.5 logs to lower than the sensitivity of the bioassay used (Lemmer and others 2004). Analogous treatment of the pen surfaces did not effectively remove the levels of scrapie infectivity over that of the control pens, indicating that this method of decontamination is not effective within a farm setting. This may be due to the high level of biological matrix that is present upon surfaces within the farm environment, which may reduce the amount of free chlorine available to inactivate any infectious prion. Remarkably 1/5 sheep introduced into pen D had also became scrapie positive within nine months, with all animals in this pen being RAMALT positive by 18 months of age. Pen D was no further away from the control pen (pen A) than any of the other pens within this barn. Localised hot spots of infectivity may be present within scrapie-contaminated environments, but it is unlikely that pen D area had an amount of scrapie contamination that was significantly different than the other areas within this building. Similarly, there were no differences in how the biosecurity of pen D was maintained, or how this pen was ventilated compared with the other pens. This observation, perhaps, indicates the slower kinetics of disease uptake within this pen and is consistent with a more thorough prion removal and recontamination. These observations may also account for the presence of inadvertent scrapie cases within other studies, where despite stringent biosecurity, control animals have become scrapie positive during challenge studies using barns that also housed scrapie-affected animals (Ryder and others 2009). The bioassay data indicate that the exposure of the sheep to a farm environment after decontamination efforts thought to be effective in removing scrapie is sufficient for the animals to become infected with scrapie. The main exposure routes within this scenario are likely to be via the oral route, during feeding and drinking, and respiratory and conjunctival routes. It has been demonstrated that scrapie infectivity can be efficiently transmitted via the nasal route in sheep (Hamir and others 2008), as is the case for CWD in both murine models and in white-tailed deer (Denkers and others 2010, 2013). Recently, it has also been demonstrated that CWD prions presented as dust when bound to the soil mineral montmorillonite can be infectious via the nasal route (Nichols and others 2013). When considering pens C and D, the actual source of the infectious agent in the pens is not known, it is possible that biologically relevant levels of prion survive on surfaces during the decontamination regimen (pen C). With the use of galvanising and painting (pen D) covering and sealing the surface of the pen, it is possible that scrapie material recontaminated the pens by the movement of infectious prions contained within dusts originating from other parts of the barn that were not decontaminated or from other areas of the farm.

 

Given that scrapie prions are widespread on the surfaces of affected farms (Maddison and others 2010a), irrespective of the source of the infectious prions in the pens, this study clearly highlights the difficulties that are faced with the effective removal of environmentally associated scrapie infectivity. This is likely to be paralleled in CWD which shows strong similarities to scrapie in terms of both the dissemination of prions into the environment and the facile mode of disease transmission. These data further contribute to the understanding that prion diseases can be highly transmissible between susceptible individuals not just by direct contact but through highly stable environmental reservoirs that are refractory to decontamination.

 

The presence of these environmentally associated prions in farm buildings make the control of these diseases a considerable challenge, especially in animal species such as goats where there is lack of genetic resistance to scrapie and, therefore, no scope to re-stock farms with animals that are resistant to scrapie.

 

Scrapie Sheep Goats Transmissible spongiform encephalopathies (TSE) Accepted October 12, 2014. Published Online First 31 October 2014

 


 

Monday, November 3, 2014

 

Persistence of ovine scrapie infectivity in a farm environment following cleaning and decontamination

 


 

PPo3-22:

 

Detection of Environmentally Associated PrPSc on a Farm with Endemic Scrapie

 

Ben C. Maddison,1 Claire A. Baker,1 Helen C. Rees,1 Linda A. Terry,2 Leigh Thorne,2 Susan J. Belworthy2 and Kevin C. Gough3 1ADAS-UK LTD; Department of Biology; University of Leicester; Leicester, UK; 2Veterinary Laboratories Agency; Surry, KT UK; 3Department of Veterinary Medicine and Science; University of Nottingham; Sutton Bonington, Loughborough UK

 

Key words: scrapie, evironmental persistence, sPMCA

 

Ovine scrapie shows considerable horizontal transmission, yet the routes of transmission and specifically the role of fomites in transmission remain poorly defined. Here we present biochemical data demonstrating that on a scrapie-affected sheep farm, scrapie prion contamination is widespread. It was anticipated at the outset that if prions contaminate the environment that they would be there at extremely low levels, as such the most sensitive method available for the detection of PrPSc, serial Protein Misfolding Cyclic Amplification (sPMCA), was used in this study. We investigated the distribution of environmental scrapie prions by applying ovine sPMCA to samples taken from a range of surfaces that were accessible to animals and could be collected by use of a wetted foam swab. Prion was amplified by sPMCA from a number of these environmental swab samples including those taken from metal, plastic and wooden surfaces, both in the indoor and outdoor environment. At the time of sampling there had been no sheep contact with these areas for at least 20 days prior to sampling indicating that prions persist for at least this duration in the environment. These data implicate inanimate objects as environmental reservoirs of prion infectivity which are likely to contribute to disease transmission.

 


 

2012

 

PO-039: A comparison of scrapie and chronic wasting disease in white-tailed deer

 

Justin Greenlee, Jodi Smith, Eric Nicholson US Dept. Agriculture; Agricultural Research Service, National Animal Disease Center; Ames, IA USA

 

snip...

 

The results of this study suggest that there are many similarities in the manifestation of CWD and scrapie in WTD after IC inoculation including early and widespread presence of PrPSc in lymphoid tissues, clinical signs of depression and weight loss progressing to wasting, and an incubation time of 21-23 months. Moreover, western blots (WB) done on brain material from the obex region have a molecular profile similar to CWD and distinct from tissues of the cerebrum or the scrapie inoculum. However, results of microscopic and IHC examination indicate that there are differences between the lesions expected in CWD and those that occur in deer with scrapie: amyloid plaques were not noted in any sections of brain examined from these deer and the pattern of immunoreactivity by IHC was diffuse rather than plaque-like.

 

*** After a natural route of exposure, 100% of WTD were susceptible to scrapie.

 

Deer developed clinical signs of wasting and mental depression and were necropsied from 28 to 33 months PI. Tissues from these deer were positive for PrPSc by IHC and WB. Similar to IC inoculated deer, samples from these deer exhibited two different molecular profiles: samples from obex resembled CWD whereas those from cerebrum were similar to the original scrapie inoculum. On further examination by WB using a panel of antibodies, the tissues from deer with scrapie exhibit properties differing from tissues either from sheep with scrapie or WTD with CWD. Samples from WTD with CWD or sheep with scrapie are strongly immunoreactive when probed with mAb P4, however, samples from WTD with scrapie are only weakly immunoreactive. In contrast, when probed with mAb’s 6H4 or SAF 84, samples from sheep with scrapie and WTD with CWD are weakly immunoreactive and samples from WTD with scrapie are strongly positive. This work demonstrates that WTD are highly susceptible to sheep scrapie, but on first passage, scrapie in WTD is differentiable from CWD.

 


 

2011

 

*** After a natural route of exposure, 100% of white-tailed deer were susceptible to scrapie.

 


 

*** We conclude that TSE infectivity is likely to survive burial for long time periods with minimal loss of infectivity and limited movement from the original burial site. However PMCA results have shown that there is the potential for rainwater to elute TSE related material from soil which could lead to the contamination of a wider area. These experiments reinforce the importance of risk assessment when disposing of TSE risk materials.

 

*** The results show that even highly diluted PrPSc can bind efficiently to polypropylene, stainless steel, glass, wood and stone and propagate the conversion of normal prion protein. For in vivo experiments, hamsters were ic injected with implants incubated in 1% 263K-infected brain homogenate. Hamsters, inoculated with 263K-contaminated implants of all groups, developed typical signs of prion disease, whereas control animals inoculated with non-contaminated materials did not.

 

PRION 2014 CONFERENCE

 

CHRONIC WASTING DISEASE CWD

 

A FEW FINDINGS ;

 

Conclusions. To our knowledge, this is the first established experimental model of CWD in TgSB3985. We found evidence for co-existence or divergence of two CWD strains adapted to Tga20 mice and their replication in TgSB3985 mice. Finally, we observed phenotypic differences between cervid-derived CWD and CWD/Tg20 strains upon propagation in TgSB3985 mice. Further studies are underway to characterize these strains.

 

We conclude that TSE infectivity is likely to survive burial for long time periods with minimal loss of infectivity and limited movement from the original burial site. However PMCA results have shown that there is the potential for rainwater to elute TSE related material from soil which could lead to the contamination of a wider area. These experiments reinforce the importance of risk assessment when disposing of TSE risk materials.

 

The results show that even highly diluted PrPSc can bind efficiently to polypropylene, stainless steel, glass, wood and stone and propagate the conversion of normal prion protein. For in vivo experiments, hamsters were ic injected with implants incubated in 1% 263K-infected brain homogenate. Hamsters, inoculated with 263K-contaminated implants of all groups, developed typical signs of prion disease, whereas control animals inoculated with non-contaminated materials did not.

 

Our data establish that meadow voles are permissive to CWD via peripheral exposure route, suggesting they could serve as an environmental reservoir for CWD. Additionally, our data are consistent with the hypothesis that at least two strains of CWD circulate in naturally-infected cervid populations and provide evidence that meadow voles are a useful tool for CWD strain typing.

 

Conclusion. CWD prions are shed in saliva and urine of infected deer as early as 3 months post infection and throughout the subsequent >1.5 year course of infection. In current work we are examining the relationship of prionemia to excretion and the impact of excreted prion binding to surfaces and particulates in the environment.

 

Conclusion. CWD prions (as inferred by prion seeding activity by RT-QuIC) are shed in urine of infected deer as early as 6 months post inoculation and throughout the subsequent disease course. Further studies are in progress refining the real-time urinary prion assay sensitivity and we are examining more closely the excretion time frame, magnitude, and sample variables in relationship to inoculation route and prionemia in naturally and experimentally CWD-infected cervids.

 

Conclusions. Our results suggested that the odds of infection for CWD is likely controlled by areas that congregate deer thus increasing direct transmission (deer-to-deer interactions) or indirect transmission (deer-to-environment) by sharing or depositing infectious prion proteins in these preferred habitats. Epidemiology of CWD in the eastern U.S. is likely controlled by separate factors than found in the Midwestern and endemic areas for CWD and can assist in performing more efficient surveillance efforts for the region.

 

Conclusions. During the pre-symptomatic stage of CWD infection and throughout the course of disease deer may be shedding multiple LD50 doses per day in their saliva. CWD prion shedding through saliva and excreta may account for the unprecedented spread of this prion disease in nature.

 

see full text and more ;

 

Monday, June 23, 2014

 

*** PRION 2014 CONFERENCE CHRONIC WASTING DISEASE CWD

 


 


 

*** Infectious agent of sheep scrapie may persist in the environment for at least 16 years***

 

Gudmundur Georgsson1, Sigurdur Sigurdarson2 and Paul Brown3

 


 

New studies on the heat resistance of hamster-adapted scrapie agent: Threshold survival after ashing at 600°C suggests an inorganic template of replication

 


 

Prion Infected Meat-and-Bone Meal Is Still Infectious after Biodiesel Production

 


 

Detection of protease-resistant cervid prion protein in water from a CWD-endemic area

 


 

A Quantitative Assessment of the Amount of Prion Diverted to Category 1 Materials and Wastewater During Processing

 


 

Rapid assessment of bovine spongiform encephalopathy prion inactivation by heat treatment in yellow grease produced in the industrial manufacturing process of meat and bone meals

 


 

Sunday, December 21, 2014

 

Mucosal immunization with an attenuated Salmonella vaccine partially protects white-tailed deer from chronic wasting disease

 


 

Friday, December 19, 2014

 

Pan-Provincial Vaccine Enterprise Inc. (PREVENT) Conducting a Chronic Wasting Disease (CWD) Vaccine Efficacy Trial in Elk

 


 

Friday, January 16, 2015

 

Indiana SENATE BILL No. 442 Miller Pete Hunting wildlife Removes exotic mammals from the animals that may be propagated or offered for hunting at a shooting preserve Makes it a Class C misdemeanor

 


 

CHRONIC WASTING DISEASE CWD TSE PRION, how much does it pay to find CWD $$$

 

CWD, spreading it around...

 

Tuesday, January 06, 2015

 

APHIS Provides Additional Information on Chronic Wasting Disease (CWD) Indemnity Requests January 5, 2015 05:26 PM EST

 


 

when an industry is catering to the public, with products which can risk human and animal health, in my opinion, you should have NO property rights. you should not be able to hide behind property rights when you are clearly risking human and animal health from your product, or the way you handle that product. if you are going to raise, grow, produce a product for the consumer, you have an obligation NOT to risk the public domain, public property, and or the wild animal populations. just my opinion. ...

 

 

Wednesday, January 28, 2015

 

Another new prion disease: relationship with central and peripheral amyloidoses

 

here we go again...

 


 

spontaneous atypical BSE ???

 

if that's the case, then France is having one hell of an epidemic of atypical BSE, probably why they stopped testing for BSE, problem solved $$$

 

As of December 2011, around 60 atypical BSE cases have currently been reported in 13 countries, *** with over one third in France.

 


 

so 20 cases of atypical BSE in France, compared to the remaining 40 cases in the remaining 12 Countries, divided by the remaining 12 Countries, about 3+ cases per country, besides Frances 20 cases. you cannot explain this away with any spontaneous BSe. ...TSS

 

Sunday, October 5, 2014

 

France stops BSE testing for Mad Cow Disease

 


 

Thursday, July 24, 2014

 

*** Protocol for further laboratory investigations into the distribution of infectivity of Atypical BSE SCIENTIFIC REPORT OF EFSA New protocol for Atypical BSE investigations

 


 

Monday, December 1, 2014

 

Germany Bovine Spongiform Encephalopathy BSE CJD TSE Prion disease A Review December 1, 2014

 


 

Wednesday, January 28, 2015

 

BOVINE HEPARIN POSITION STATEMENT ON THE REINTRODUCTION and POTENTIAL BSE TSE PRION RISK FACTORS THEREFROM

 


 

Thursday, January 29, 2015

 

Identification of H-type BSE in Portugal

 


 

Thursday, January 29, 2015

 

OIE REPORT Bovine spongiform encephalopathy Prion (atypical BSE type H), Norway Information received on 29/01/2015

 


 

Tuesday, December 16, 2014

 

Evidence for zoonotic potential of ovine scrapie prions

 

Hervé Cassard,1, n1 Juan-Maria Torres,2, n1 Caroline Lacroux,1, Jean-Yves Douet,1, Sylvie L. Benestad,3, Frédéric Lantier,4, Séverine Lugan,1, Isabelle Lantier,4, Pierrette Costes,1, Naima Aron,1, Fabienne Reine,5, Laetitia Herzog,5, Juan-Carlos Espinosa,2, Vincent Beringue5, & Olivier Andréoletti1, Affiliations Contributions Corresponding author Journal name: Nature Communications Volume: 5, Article number: 5821 DOI: doi:10.1038/ncomms6821 Received 07 August 2014 Accepted 10 November 2014 Published 16 December 2014 Article tools Citation Reprints Rights & permissions Article metrics

 

Abstract

 

Although Bovine Spongiform Encephalopathy (BSE) is the cause of variant Creutzfeldt Jakob disease (vCJD) in humans, the zoonotic potential of scrapie prions remains unknown. Mice genetically engineered to overexpress the human ​prion protein (tgHu) have emerged as highly relevant models for gauging the capacity of prions to transmit to humans. These models can propagate human prions without any apparent transmission barrier and have been used used to confirm the zoonotic ability of BSE. Here we show that a panel of sheep scrapie prions transmit to several tgHu mice models with an efficiency comparable to that of cattle BSE. The serial transmission of different scrapie isolates in these mice led to the propagation of prions that are phenotypically identical to those causing sporadic CJD (sCJD) in humans. These results demonstrate that scrapie prions have a zoonotic potential and raise new questions about the possible link between animal and human prions.

 

Subject terms: Biological sciences• Medical research At a glance

 


 

why do we not want to do TSE transmission studies on chimpanzees $

 

5. A positive result from a chimpanzee challenged severly would likely create alarm in some circles even if the result could not be interpreted for man. I have a view that all these agents could be transmitted provided a large enough dose by appropriate routes was given and the animals kept long enough. Until the mechanisms of the species barrier are more clearly understood it might be best to retain that hypothesis.

 

snip...

 

R. BRADLEY

 


 

1: J Infect Dis 1980 Aug;142(2):205-8

 

Oral transmission of kuru, Creutzfeldt-Jakob disease, and scrapie to nonhuman primates.

 

Gibbs CJ Jr, Amyx HL, Bacote A, Masters CL, Gajdusek DC.

 

Kuru and Creutzfeldt-Jakob disease of humans and scrapie disease of sheep and goats were transmitted to squirrel monkeys (Saimiri sciureus) that were exposed to the infectious agents only by their nonforced consumption of known infectious tissues. The asymptomatic incubation period in the one monkey exposed to the virus of kuru was 36 months; that in the two monkeys exposed to the virus of Creutzfeldt-Jakob disease was 23 and 27 months, respectively; and that in the two monkeys exposed to the virus of scrapie was 25 and 32 months, respectively. Careful physical examination of the buccal cavities of all of the monkeys failed to reveal signs or oral lesions. One additional monkey similarly exposed to kuru has remained asymptomatic during the 39 months that it has been under observation.

 

snip...

 

The successful transmission of kuru, Creutzfeldt-Jakob disease, and scrapie by natural feeding to squirrel monkeys that we have reported provides further grounds for concern that scrapie-infected meat may occasionally give rise in humans to Creutzfeldt-Jakob disease.

 

PMID: 6997404

 


 

Recently the question has again been brought up as to whether scrapie is transmissible to man. This has followed reports that the disease has been transmitted to primates. One particularly lurid speculation (Gajdusek 1977) conjectures that the agents of scrapie, kuru, Creutzfeldt-Jakob disease and transmissible encephalopathy of mink are varieties of a single "virus". The U.S. Department of Agriculture concluded that it could "no longer justify or permit scrapie-blood line and scrapie-exposed sheep and goats to be processed for human or animal food at slaughter or rendering plants" (ARC 84/77)" The problem is emphasised by the finding that some strains of scrapie produce lesions identical to the once which characterise the human dementias"

 

Whether true or not. the hypothesis that these agents might be transmissible to man raises two considerations. First, the safety of laboratory personnel requires prompt attention. Second, action such as the "scorched meat" policy of USDA makes the solution of the acrapie problem urgent if the sheep industry is not to suffer grievously.

 

snip...

 

76/10.12/4.6

 


 

Nature. 1972 Mar 10;236(5341):73-4.

 

Transmission of scrapie to the cynomolgus monkey (Macaca fascicularis).

 

Gibbs CJ Jr, Gajdusek DC.

 

Nature 236, 73 - 74 (10 March 1972); doi:10.1038/236073a0

 

Transmission of Scrapie to the Cynomolgus Monkey (Macaca fascicularis)

 

C. J. GIBBS jun. & D. C. GAJDUSEK

 

National Institute of Neurological Diseases and Stroke, National Institutes of Health, Bethesda, Maryland

 

SCRAPIE has been transmitted to the cynomolgus, or crab-eating, monkey (Macaca fascicularis) with an incubation period of more than 5 yr from the time of intracerebral inoculation of scrapie-infected mouse brain. The animal developed a chronic central nervous system degeneration, with ataxia, tremor and myoclonus with associated severe scrapie-like pathology of intensive astroglial hypertrophy and proliferation, neuronal vacuolation and status spongiosus of grey matter. The strain of scrapie virus used was the eighth passage in Swiss mice (NIH) of a Compton strain of scrapie obtained as ninth intracerebral passage of the agent in goat brain, from Dr R. L. Chandler (ARC, Compton, Berkshire).

 


 


 


 


 

2001

 

Suspect symptoms

 

What if you can catch old-fashioned CJD by eating meat from a sheep infected with scrapie?

 

28 Mar 01

 

Like lambs to the slaughter

 

31 March 2001

 

by Debora MacKenzie Magazine issue 2284.

 

FOUR years ago, Terry Singeltary watched his mother die horribly from a degenerative brain disease. Doctors told him it was Alzheimer's, but Singeltary was suspicious. The diagnosis didn't fit her violent symptoms, and he demanded an autopsy. It showed she had died of sporadic Creutzfeldt-Jakob disease.

 

Most doctors believe that sCJD is caused by a prion protein deforming by chance into a killer. But Singeltary thinks otherwise. He is one of a number of campaigners who say that some sCJD, like the variant CJD related to BSE, is caused by eating meat from infected animals. Their suspicions have focused on sheep carrying scrapie, a BSE-like disease that is widespread in flocks across Europe and North America.

 

Now scientists in France have stumbled across new evidence that adds weight to the campaigners' fears. To their complete surprise, the researchers found that one strain of scrapie causes the same brain damage in mice as sCJD.

 

"This means we cannot rule out that at least some sCJD may be caused by some strains of scrapie," says team member Jean-Philippe Deslys of the French Atomic Energy Commission's medical research laboratory in Fontenay-aux-Roses, south-west of Paris. Hans Kretschmar of the University of Göttingen, who coordinates CJD surveillance in Germany, is so concerned by the findings that he now wants to trawl back through past sCJD cases to see if any might have been caused by eating infected mutton or lamb.

 

Scrapie has been around for centuries and until now there has been no evidence that it poses a risk to human health. But if the French finding means that scrapie can cause sCJD in people, countries around the world may have overlooked a CJD crisis to rival that caused by BSE.

 

Deslys and colleagues were originally studying vCJD, not sCJD. They injected the brains of macaque monkeys with brain from BSE cattle, and from French and British vCJD patients. The brain damage and clinical symptoms in the monkeys were the same for all three. Mice injected with the original sets of brain tissue or with infected monkey brain also developed the same symptoms.

 

As a control experiment, the team also injected mice with brain tissue from people and animals with other prion diseases: a French case of sCJD; a French patient who caught sCJD from human-derived growth hormone; sheep with a French strain of scrapie; and mice carrying a prion derived from an American scrapie strain. As expected, they all affected the brain in a different way from BSE and vCJD. But while the American strain of scrapie caused different damage from sCJD, the French strain produced exactly the same pathology.

 

"The main evidence that scrapie does not affect humans has been epidemiology," says Moira Bruce of the neuropathogenesis unit of the Institute for Animal Health in Edinburgh, who was a member of the same team as Deslys. "You see about the same incidence of the disease everywhere, whether or not there are many sheep, and in countries such as New Zealand with no scrapie." In the only previous comparisons of sCJD and scrapie in mice, Bruce found they were dissimilar.

 

But there are more than 20 strains of scrapie, and six of sCJD. "You would not necessarily see a relationship between the two with epidemiology if only some strains affect only some people," says Deslys. Bruce is cautious about the mouse results, but agrees they require further investigation. Other trials of scrapie and sCJD in mice, she says, are in progress.

 

People can have three different genetic variations of the human prion protein, and each type of protein can fold up two different ways. Kretschmar has found that these six combinations correspond to six clinical types of sCJD: each type of normal prion produces a particular pathology when it spontaneously deforms to produce sCJD.

 

But if these proteins deform because of infection with a disease-causing prion, the relationship between pathology and prion type should be different, as it is in vCJD. "If we look at brain samples from sporadic CJD cases and find some that do not fit the pattern," says Kretschmar, "that could mean they were caused by infection."

 

There are 250 deaths per year from sCJD in the US, and a similar incidence elsewhere. Singeltary and other US activists think that some of these people died after eating contaminated meat or "nutritional" pills containing dried animal brain. Governments will have a hard time facing activists like Singeltary if it turns out that some sCJD isn't as spontaneous as doctors have insisted.

 

Deslys's work on macaques also provides further proof that the human disease vCJD is caused by BSE. And the experiments showed that vCJD is much more virulent to primates than BSE, even when injected into the bloodstream rather than the brain. This, says Deslys, means that there is an even bigger risk than we thought that vCJD can be passed from one patient to another through contaminated blood transfusions and surgical instruments.

 


 

Tuesday, December 23, 2014

 

*** FDA PART 589 -- SUBSTANCES PROHIBITED FROM USE IN ANIMAL FOOD OR FEED VIOLATIONS OFFICIAL ACTION INDICATED OAI UPDATE DECEMBER 2014 BSE TSE PRION

 


 


 

 

CWD TO HUMANS, AND RISK FACTORS THERE FROM (see latest science)

 

Tuesday, November 04, 2014

 

*** Six-year follow-up of a point-source exposure to CWD contaminated venison in an Upstate New York community: risk behaviours and health outcomes 2005–2011

 


 


 

Friday, December 5, 2014

 

*** SPECIAL ALERT The OIE recommends strengthening animal disease surveillance worldwide OIE

 

BSE TSE PRION AKA MAD COW DISEASE ? ‘’the silence was deafening’’ ...tss

 


 

 

 

 

 

 

Comment from Terry Singeltary Sr.


Comment

Docket No. APHIS-2014-0107 Bovine Spongiform Encephalopathy; Importation of Animals and Animal Products Singeltary Submission ;

I believe that there is more risk to the world from Transmissible Spongiform Encephalopathy TSE prion aka mad cow type disease now, coming from the United States and all of North America, than there is risk coming to the USA and North America, from other Countries. I am NOT saying I dont think there is any risk for the BSE type TSE prion coming from other Countries, I am just saying that in 2015, why is the APHIS/USDA/FSIS/FDA still ignoring these present mad cow risk factors in North America like they are not here?

North America has more strains of TSE prion disease, in more species (excluding zoo animals in the early BSE days, and excluding the Feline TSE and or Canine TSE, because they dont look, and yes, there has been documented evidence and scientific studies, and DEFRA Hound study, that shows the canine spongiform encephalopathy is very possible, if it has not already happened, just not documented), then any other Country in the world. Mink TME, Deer Elk cervid CWD (multiple strains), cBSE cattle, atypical L-type BSE cattle, atypical H-type BSE cattle, atyical HG type BSE cow (the only cow documented in the world to date with this strain), typical sheep goat Scrapie (multiple strains), and the atypical Nor-98 Scrapie, which has been linked to sporadic CJD, Nor-98 atypical Scrapie has spread from coast to coast. sporadic CJD on the rise, with different strains mounting, victims becoming younger, with the latest nvCJD human mad cow case being documented in Texas again, this case, NOT LINKED TO EUROPEAN TRAVEL CDC.

typical BSE can propagate as nvCJD and or sporadic CJD (Collinge et al), and sporadic CJD has now been linked to atypical BSE, Scrapie and atypical Scrapie, and scientist are very concerned with CWD TSE prion in the Cervid populations. in my opinion, the BSE MRR policy, which overtook the BSE GBR risk assessments for each country, and then made BSE confirmed countries legal to trade mad cow disease, which was all brought forth AFTER that fateful day December 23, 2003, when the USA lost its gold card i.e. BSE FREE status, thats the day it all started. once the BSE MRR policy was shoved down every countries throat by USDA inc and the OIE, then the legal trading of Scrapie was validated to be a legal trading commodity, also shoved through by the USDA inc and the OIE, the world then lost 30 years of attempted eradication of the BSE TSE prion disease typical and atypical strains, and the BSE TSE Prion aka mad cow type disease was thus made a legal trading commodity, like it or not. its all about money now folks, trade, to hell with human health with a slow incubating disease, that is 100% fatal once clinical, and forget the fact of exposure, sub-clinical infection, and friendly fire there from i.e. iatrogenic TSE prion disease, the pass it forward mode of the TSE PRION aka mad cow type disease. its all going to be sporadic CJD or sporadic ffi, or sporadic gss, or now the infamous VPSPr. ...problem solved $$$

the USDA/APHIS/FSIS/FDA triple mad cow BSE firewall, well, that was nothing but ink on paper.

for this very reason I believe the BSE MRR policy is a total failure, and that this policy should be immediately withdrawn, and set back in place the BSE GBR Risk Assessments, with the BSE GBR risk assessments set up to monitor all TSE PRION disease in all species of animals, and that the BSE GBR risk assessments be made stronger than before.

lets start with the recent notice that beef from Ireland will be coming to America.

Ireland confirmed around 1655 cases of mad cow disease. with the highest year confirming about 333 cases in 2002, with numbers of BSE confirmed cases dropping from that point on, to a documentation of 1 confirmed case in 2013, to date. a drastic decrease in the feeding of cows to cows i.e. the ruminant mad cow feed ban, and the enforcement of that ban, has drastically reduced the number of BSE cases in Europe, minus a few BABs or BARBs. a far cry from the USDA FDA triple BSE firewall, which was nothing more than ink on paper, where in 2007, in one week recall alone, some 10 MILLION POUNDS OF BANNED POTENTIAL MAD COW FEED WENT OUT INTO COMMERCE IN THE USA. this is 10 years post feed ban. in my honest opinion, due to the blatant cover up of BSE TSE prion aka mad cow disease in the USA, we still have no clue as to the true number of cases of BSE mad cow disease in the USA or North America as a whole. ...just saying.

Number of reported cases of bovine spongiform encephalopathy (BSE) in farmed cattle worldwide* (excluding the United Kingdom)

Country/Year

snip...please see attached pdf file, with references of breaches in the USA triple BSE mad cow firewalls, and recent science on the TSE prion disease. ...TSS

Attachments

 (1)

Docket No. APHIS-2014-0107 Bovine Spongiform Encephalopathy; Importation of Animals and Animal Products Singeltary Submission

View Attachment:


 

 

Sunday, January 11, 2015

 

Docket No. APHIS-2014-0107 Bovine Spongiform Encephalopathy; Importation of Animals and Animal Products Singeltary Submission

 


 


 

 

 

 

 

*** HUMAN MAD COW DISEASE nvCJD TEXAS CASE NOT LINKED TO EUROPEAN TRAVEL CDC ***

 

Sunday, November 23, 2014

 

*** Confirmed Variant Creutzfeldt-Jakob Disease (variant CJD) Case in Texas in June 2014 confirmed as USA case NOT European

 

the patient had resided in Kuwait, Russia and Lebanon. The completed investigation did not support the patient's having had extended travel to European countries, including the United Kingdom, or travel to Saudi Arabia. The specific overseas country where this patient’s infection occurred is less clear largely because the investigation did not definitely link him to a country where other known vCJD cases likely had been infected.

 


 

Sunday, December 14, 2014

 

*** ALERT new variant Creutzfeldt Jakob Disease nvCJD or vCJD, sporadic CJD strains, TSE prion aka Mad Cow Disease United States of America Update December 14, 2014 Report

 


 

Wednesday, January 28, 2015

 

Another new prion disease: relationship with central and peripheral amyloidoses here we go again...

 


 

 

Thursday, January 15, 2015

 

41-year-old Navy Commander with sporadic Creutzfeldt–Jakob disease CJD TSE Prion: Case Report

 


 

Subject: *** Becky Lockhart 46, Utah’s first female House speaker, dies diagnosed with the extremely rare Creutzfeldt-Jakob disease aka mad cow type disease

 

what is CJD ? just ask USDA inc., and the OIE, they are still feeding the public and the media industry fed junk science that is 30 years old.

 

why doesn’t some of you try reading the facts, instead of rubber stamping everything the USDA inc says.

 

sporadic CJD has now been linked to BSE aka mad cow disease, Scrapie, and there is much concern now for CWD and risk factor for humans.

 

My sincere condolences to the family and friends of the House Speaker Becky Lockhart. I am deeply saddened hear this.

 

with that said, with great respect, I must ask each and every one of you Politicians that are so deeply saddened to hear of this needless death of the Honorable House Speaker Becky Lockhart, really, cry me a friggen river. I am seriously going to ask you all this...I have been diplomatic for about 17 years and it has got no where. people are still dying. so, are you all stupid or what??? how many more need to die ??? how much is global trade of beef and other meat products that are not tested for the TSE prion disease, how much and how many bodies is this market worth?

 

Saturday, January 17, 2015

 

*** Becky Lockhart 46, Utah’s first female House speaker, dies diagnosed with the extremely rare Creutzfeldt-Jakob disease

 


 


 

Thursday, January 22, 2015

 

Transmission properties of atypical Creutzfeldt-Jakob disease: a clue to disease etiology?

 


 

Tuesday, December 30, 2014

 

TSEAC USA Reason For Recalls Blood products, collected from a donors considered to be at increased risk for Creutzfeldt-Jakob Disease (CJD), were distributed END OF YEAR REPORT 2014

 


 

who’s kidding whom $$$ i.e. USDA INC AND THE OIE

 

2014

 

***Moreover, L-BSE has been transmitted more easily to transgenic mice overexpressing a human PrP [13,14] or to primates [15,16] than C-BSE.

 

***It has been suggested that some sporadic CJD subtypes in humans may result from an exposure to the L-BSE agent.

 

*** Lending support to this hypothesis, pathological and biochemical similarities have been observed between L-BSE and an sCJD subtype (MV genotype at codon 129 of PRNP) [17], and between L-BSE infected non-human primate and another sCJD subtype (MM genotype) [15].

 

snip...

 


 

Monday, October 10, 2011

 

EFSA Journal 2011 The European Response to BSE: A Success Story

 

snip...

 

EFSA and the European Centre for Disease Prevention and Control (ECDC) recently delivered a scientific opinion on any possible epidemiological or molecular association between TSEs in animals and humans (EFSA Panel on Biological Hazards (BIOHAZ) and ECDC, 2011). This opinion confirmed Classical BSE prions as the only TSE agents demonstrated to be zoonotic so far

 

*** but the possibility that a small proportion of human cases so far classified as "sporadic" CJD are of zoonotic origin could not be excluded.

 

*** Moreover, transmission experiments to non-human primates suggest that some TSE agents in addition to Classical BSE prions in cattle (namely L-type Atypical BSE, Classical BSE in sheep, transmissible mink encephalopathy (TME) and chronic wasting disease (CWD) agents) might have zoonotic potential.

 

snip...

 


 


 

Thursday, August 12, 2010

 

Seven main threats for the future linked to prions

 

First threat

 

The TSE road map defining the evolution of European policy for protection against prion diseases is based on a certain numbers of hypotheses some of which may turn out to be erroneous. In particular, a form of BSE (called atypical Bovine Spongiform Encephalopathy), recently identified by systematic testing in aged cattle without clinical signs, may be the origin of classical BSE and thus potentially constitute a reservoir, which may be impossible to eradicate if a sporadic origin is confirmed.

 

*** Also, a link is suspected between atypical BSE and some apparently sporadic cases of Creutzfeldt-Jakob disease in humans.

 

*** These atypical BSE cases constitute an unforeseen first threat that could sharply modify the European approach to prion diseases.

 

Second threat

 

snip...

 


 

 

Terry S. Singeltary Sr.

P.O. Box 42

Bacliff, Texas USA 77518

Thursday, January 29, 2015

OIE REPORT Bovine spongiform encephalopathy Prion (atypical BSE type H), Norway Information received on 29/01/2015

Bovine spongiform encephalopathy ,Norway Information received on 29/01/2015

 

from Dre Kristina Landsverk, Chief Veterinary Officer, Norwegian Food Safety Authority, Ministry of Agriculture and Food, Brumunddal, Norway

 

Summary Report type Immediate notification Date of start of the event 16/01/2015 Date of pre-confirmation of the event 20/01/2015 Report date 29/01/2015 Date submitted to OIE 29/01/2015 Reason for notification First occurrence of a listed disease Manifestation of disease Sub-clinical infection Causal agent Prion (atypical BSE type H) Nature of diagnosis Laboratory (advanced) This event pertains to the whole country

 

New outbreaks Summary of outbreaks Total outbreaks: 1 Outbreak Location NORD-TRONDELAG ( Verran, Tua, District office Innherred og Fosen, Region office Trøndelag og Møre og Romdal ) Total animals affected Species Susceptible Cases Deaths Destroyed Slaughtered Cattle 27 1 0 1 0 Outbreak statistics Species Apparent morbidity rate Apparent mortality rate Apparent case fatality rate Proportion susceptible animals lost* Cattle 3.70% 0.00% 0.00% 3.70%

 

* Removed from the susceptible population through death, destruction and/or slaughter;

 

Epidemiology Source of the outbreak(s) or origin of infection Unknown or inconclusive Epidemiological comments Based on status on 29 January 2015: On 20 January 2015, the Norwegian Veterinary Institute reported suspicion of BSE on a cow in Norway, based on initial test done on CNS material. Part of this material was sent to European Union Reference Laboratory in Weybridge (21 January 2015) for verification of diagnosis. The affected cow was a 15-year-old and born in Norway. The dam was imported from Sweden. The cow did not show clinical signs of neurological disease before she was killed (12 January 2015) due to old age and injuries. The BSE test was taken as part of the BSE surveillance program. The Norwegian Food Safety Authority (NFSA) has put restrictions on movement on the farm, and performed epidemiological investigations. The NFSA has identified four risk animals, according to relevant legislation. These animals are also placed under official movement restrictions. The four identified risk animals will be killed and disposed by incineration according to European Union legislation. The epidemiological investigation including tracing of risk animals from the holding of origin as well as the present holding has identified 2 offspring borne within two years prior to the incident in addition to 2 cattle belonging either to (1) the cohort of animals born in the same herd as the affected animal within 12 months preceding or following the date of birth of the affected cow or (2) the cohort of animals which at any time during the first year of their lives were reared together with the affected cow during her first year of life. Progeny borne within two years prior to the incident and the cohort of risk animals are put under movement restrictions and the killing and destruction of these animals will be carried into effect as soon as possible. The affected cow’s carcass has been completely destroyed. The NFSA ensures that the cow’s carcass has been processed by pressure sterilisation in a Category 1 processing plant and that the resulting material has been sent for incineration/co-incineration in accordance with the By-Products Regulation.

 

Control measures Measures applied Movement control inside the country Screening No vaccination No treatment of affected animals Measures to be applied Modified stamping out

 

Diagnostic test results Laboratory name and type Norwegian Veterinary Institute ( National laboratory ) Tests and results Species Test Test date Result Cattle enzyme-linked immunosorbent assay (ELISA) 20/01/2015 Positive Cattle western blot 20/01/2015 Positive Laboratory name and type EU Reference Laboratory, Animal and Plant Health Agency (APHA), Weybridge (United Kingdom) ( OIE’s Reference Laboratory ) Tests and results Species Test Test date Result Cattle immunohistochemical test 28/01/2015 Positive Cattle western blot 28/01/2015 Positive

 

Future Reporting The event is continuing. Weekly follow-up reports will be submitted.

 


 

Encéphalopathie spongiforme bovine ,Norvège Information reçue le 29/01/2015 de Dre Kristina Landsverk, Chief Veterinary Officer, Norwegian Food Safety Authority, Ministry of Agriculture and Food, Brumunddal, Norvège

 

Résumé Type de rapport Notification immédiate Date de début de l’événement 16/01/2015 Date de pré-confirmation de l´événement 20/01/2015 Date du rapport 29/01/2015 Date d'envoi à l'OIE 29/01/2015 Raison de notification Apparition pour la première fois d’une maladie listée par l'OIE Manifestation de la maladie Infection sub-clinique Agent causal Prion (EEB atypique, type H) Nature du diagnostic Tests approfondis en laboratoire (i.e. virologie, microscopie électronique, biologie moléculaire, immunologie) Cet événement se rapporte à tout le pays

 

Nouveaux foyers Récapitulatif des foyers Nombre total de foyers : 1 Localisation du foyer NORD-TRONDELAG ( Verran, Tua, District office Innherred og Fosen, Region office Trøndelag og Møre og Romdal ) Nombre total d'animaux atteints Espèce(s) Sensibles Cas Morts Détruits Abattus Bovins 27 1 0 1 0 Statistiques sur le foyer Espèce(s) Taux de morbidité apparent Taux de mortalité apparent Taux de fatalité apparent Proportion d'animaux sensibles perdus* Bovins 3.70% 0.00% 0.00% 3.70%

 

* Soustraits de la population sensible suite à la mort, à l´abattage et/ou à la destruction;

 

Epidémiologie Source du/des foyer(s) ou origine de l´infection Inconnue ou incertaine Autres renseignements épidémiologiques / Commentaires Situation au 29 janvier 2015 : Le 20 janvier 2015, l'Institut vétérinaire norvégien a informé d’une suspicion d’EEB chez une vache en Norvège en se basant sur un test initial effectué sur du matériel du SNC. Une partie de ce matériel a été envoyé au Laboratoire de référence de l'Union européenne à Weybridge (21 janvier 2015) pour vérification du diagnostic. La vache atteinte était âgée de 15 ans et était née en Norvège. La mère avait été importée de Suède. La vache n'a pas montré de signes cliniques de maladie neurologique avant d'être abattue en raison de son âge et de lésions (12 janvier 2015). Le test pour l’EEB a été effectué dans le cadre du programme de surveillance de l’EEB. L'Autorité norvégienne de sécurité alimentaire (NFSA) a mis en œuvre des restrictions aux déplacements dans l’élevage et a effectué des enquêtes épidémiologiques. La NFSA a identifié quatre animaux à risque, conformément à la législation pertinente. Les déplacements de ces animaux sont également soumis à des restrictions officielles. Les quatre animaux à risque identifiés seront abattus et éliminés par incinération conformément à la législation de l'Union européenne. Lors de l'enquête épidémiologique y compris l’enquête en amont des animaux à risque de l'exploitation d'origine ainsi que de l’exploitation actuelle ont été identifiés 2 descendants nés dans les deux ans précédant l'incident en plus de 2 bovins appartenant soit à (1) la cohorte d’animaux nés dans le même troupeau que l'animal atteint dans les 12 mois précédant ou suivant la date de naissance de la vache atteinte soit à (2) la cohorte d’animaux qui au cours de la première année de leur vies ont été élevés avec la vache atteinte au cours de sa première année de vie. Les déplacements de la descendance née dans les deux années qui ont précédé l'incident et de la cohorte d’animaux à risque sont soumis à des restrictions et l’abattage et la destruction de ces animaux seront effectués dès que possible. La carcasse de la vache atteinte a été complètement détruite. La NFSA s’assure que la carcasse de la vache a été traitée par stérilisation sous pression dans une usine de transformation de catégorie 1 et que le matériau résultant a été envoyé à l'incinération / co-incinération conformément aux dispositions du règlement sur les sous-produits animaux.

 

Mesures de lutte Mesure de lutte appliquées Restriction des déplacements à l'intérieur du pays Dépistage Pas de vaccination Aucun traitement des animaux atteints Mesures à appliquer Abattage sanitaire partiel

 

Résultats des tests de diagnostics Nom du laboratoire et type Laboratoire de référence de l'Union européenne, Agence de la santé animale et végétale (APHA), Weybridge (Royaume-Uni) ( Laboratoire de référence de l’OIE ) Tests et résultats Espèce(s) Test Date du test Résultat Bovins examen immunohistochimique 28/01/2015 Positif Bovins western blot 28/01/2015 Positif Nom du laboratoire et type Institut vétérinaire norvégien ( Laboratoire national ) Tests et résultats Espèce(s) Test Date du test Résultat Bovins méthode de dosage immuno-enzymatique (ELISA) 20/01/2015 Positif Nom du laboratoire et type Institut vétérinaire norvégien ( Laboratoire national ) Tests et résultats Espèce(s) Test Date du test Résultat Bovins western blot 20/01/2015 Positif

 

Rapports futurs Cet événement se poursuit. Des rapports de suivi hebdomadaires devront être envoyés.

 


 

Encefalopatía espongiforme bovina ,Noruega Información recibida el 29/01/2015 desde Dre Kristina Landsverk, Chief Veterinary Officer, Norwegian Food Safety Authority, Ministry of Agriculture and Food, Brumunddal, Noruega

 

Resumen Tipo de informe Notificación inmediata Fecha del inicio del evento 16/01/2015 Fecha de pre-confirmación del evento 20/01/2015 Fecha del informe 29/01/2015 Fecha de envio del informe a la OIE 29/01/2015 Motivo de la notificación Aparición por primera vez de una enfermedad de la Lista de la OIE Manifestación de la enfermedad Infección sub-clínica Agente causal Prion (EEB atípica, tipo H) Naturaleza del diagnóstico Pruebas de diagnóstico de laboratorio avanzadas (ej. virología, microscopía electrónica, biología molecular e inmunología) Este evento concierne todo el país

 

Nuevos focos Resumen de los focos Número total de focos: 1 Localización del foco NORD-TRONDELAG ( Verran, Tua, District office Innherred og Fosen, Region office Trøndelag og Møre og Romdal ) Número total de animales afectados Especies Susceptibles Casos Muertos Destruidos Sacrificados Bovinos 27 1 0 1 0 Estadística del foco Especies Tasa de morbilidad aparente Tasa de mortalidad aparente Tasa de fatalidad aparente Proporción de animales susceptibles perdidos* Bovinos 3.70% 0.00% 0.00% 3.70%

 

* Descontados de la población susceptible a raíz de su muerte, destrucción o sacrificio;

 

Epidemiología Fuente del o de los focos u origen de la infección Desconocida o no concluyente Otros detalles epidemiológicos / comentarios Situación al 29 de enero de 2015: El 20 de enero de 2015, el Instituto de veterinaria noruego informó de una sospecha de EEB en una vaca en Noruega basada en una prueba inicial realizada con material del SNC. Parte de este material se envió al Laboratorio de referencia de la Unión Europea en Weybridge (21 de enero de 2015) para verificar el diagnóstico. La vaca afectada tenía 15 años y nació en Noruega. La madre fue importada de Suecia. La vaca no mostró signos clínicos de enfermedad neurológica antes de ser eliminada por su edad avanzada y lesiones (12 de enero de 2015). La prueba para la EEB fue realizada en el marco del programa de vigilancia para la EEB. La Autoridad noruega de seguridad alimentaria (NFSA) ha impuesto restricciones a los desplazamientos en la explotación y ha realizado las investigaciones epidemiológicas. La NFSA ha identificado cuatro animales de riesgo, de acuerdo con la legislación pertinente. Los desplazamientos de estos animales también son sometidos a las restricciones oficiales. Los cuatro animales de riesgo identificados serán eliminados y destruidos por incineración de acuerdo con la legislación de la Unión Europea. En la investigación epidemiológica incluido el rastreo de los animales de riesgo de la explotación de origen así como de la explotación actual se han identificado 2 descendientes nacidos en los dos años anteriores al incidente además de 2 bovinos pertenecientes a (1) la cohorte de animales nacidos en el mismo rebaño que el animal afectado en los 12 meses anteriores o posteriores a la fecha de nacimiento de la vaca afectada o a (2) la cohorte de animales que en cualquier momento durante el primer año de vida fueron criados con la vaca afectada durante su primer año de vida. Los desplazamientos de la descendencia nacida en los dos años anteriores al incidente y de la cohorte de animales de riesgo están sometidos a restricciones y la matanza y la destrucción de estos animales se llevará a cabo lo antes posible. La canal de la vaca afectada ha sido completamente destruida. La NFSA se asegura de que la canal de la vaca ha sido procesada por esterilización a presión en una planta de transformación de la categoría 1 y de que el material resultante ha sido enviado para su incineración/co-incineración de conformidad con el reglamento relativo a los subproductos de origen animal.

 

Medidas de Control Medidas implementadas Restricción de los movimientos en el interior del país Tamizaje Vacunación: no Ningún tratamiento de los animales afectados Medidas para implementar Sacrificio sanitario parcial

 

Resultados de las pruebas diagnósticas Nombre y tipo de laboratorio Laboratorio de referencia de la Unión Europea, Agencia de sanidad animal y vegetal (APHA), Weybridge (Reino Unido) ( Laboratorio de referencia de la OIE ) Pruebas y resultados Especies Prueba Fecha de la prueba Resultados Bovinos examen inmunohistoquímico 28/01/2015 Positivo Bovinos western blot 28/01/2015 Positivo Nombre y tipo de laboratorio Instituto de veterinaria noruego ( Laboratorio nacional ) Pruebas y resultados Especies Prueba Fecha de la prueba Resultados Bovinos prueba inmunoenzimática (ELISA) 20/01/2015 Positivo Bovinos western blot 20/01/2015 Positivo

 

Informes futuros El episodio continúa. Informes de seguimiento semanales serán enviados

 

<!--[endif]—>

 


 

Scientific Report of the European Food Safety Authority on the Assessment of the Geographical BSE-Risk (GBR) of NORWAY

 

Question N° EFSA-Q-2003-083

 

Adopted July 2004

 


 

Thursday, January 29, 2015

 

Atypical H-TYPE BSE Case Confirmed in Norway

 


 

Wednesday, January 21, 2015

 

Norway detects "probable" case of mad cow disease

 




UPDATE...FINAL REPORT...TSS


Bovine spongiform encephalopathy, Norway

 

Information received on 20/02/2015 from Dre Kristina Landsverk, Chief Veterinary Officer, Norwegian Food Safety Authority, Ministry of Agriculture and Food, Brumunddal, Norway

 

Summary

 

Report type Follow-up report No. 2 (Final report) Date of start of the event 16/01/2015 Date of pre-confirmation of the event 20/01/2015 Report date 20/02/2015 Date submitted to OIE 20/02/2015 Date event resolved 03/02/2015 Reason for notification First occurrence of a listed disease Manifestation of disease Sub-clinical infection Causal agent Prion (atypical BSE type H) Nature of diagnosis Laboratory (advanced) This event pertains to the whole country Related reports Immediate notification (29/01/2015) Follow-up report No. 1 (06/02/2015) Follow-up report No. 2 (20/02/2015)

 

Outbreaks There are no new outbreaks in this report

 

Epidemiology

 

Source of the outbreak(s) or origin of infection Unknown or inconclusive Probably spontaneous Epidemiological comments Based on status on 20 February 2015: The four risk animals are killed and all of them tested negative for BSE. The four risk animals are all incinerated (with reference to NFSA [Norwegian Food Safety Authority] inspection-system Mats).

 

Control measures

 

Measures applied Movement control inside the country Screening Modified stamping out No vaccination No treatment of affected animals Measures to be applied No other measures

 

 Future Reporting

 

The event is resolved. No more reports will be submitted.

 


 

 > Source of the outbreak(s) or origin of infection Unknown or inconclusive Probably spontaneous

 

Discussion:

 

The C, L and H type BSE cases in Canada exhibit molecular characteristics similar to those described for classical and atypical BSE cases from Europe and Japan.

 

*** This supports the theory that the importation of BSE contaminated feedstuff is the source of C-type BSE in Canada.

 

*** It also suggests a similar cause or source for atypical BSE in these countries. ***

 

see page 176 of 201 pages...tss

 


 

*** PLOS Singeltary reply ; Molecular, Biochemical and Genetic Characteristics of BSE in Canada Singeltary reply ;

 


 

PLOS Singeltary Comment ;

 

*** ruminant feed ban for cervids in the United States ? ***

 

31 Jan 2015 at 20:14 GMT

 


 

Saturday, January 24, 2015

 

Bovine Spongiform Encephalopathy: Atypical Pros and Cons

 


 

Saturday, January 31, 2015

 

RAPID ADVICE 17-2014 : Evaluation of the risk for public health of casings in countries with a “negligible risk status for BSE” and on the risk of modification of the list of specified risk materials (SRM) with regard to BSE

 


 

10,000,000+ LBS. of PROHIBITED BANNED MAD COW FEED I.E. BLOOD LACED MBM IN COMMERCE USA 2007

 

Date: March 21, 2007 at 2:27 pm PST

 

RECALLS AND FIELD CORRECTIONS: VETERINARY MEDICINES -- CLASS II

 

PRODUCT

 

Bulk cattle feed made with recalled Darling's 85% Blood Meal, Flash Dried, Recall # V-024-2007

 

CODE

 

Cattle feed delivered between 01/12/2007 and 01/26/2007

 

RECALLING FIRM/MANUFACTURER

 

Pfeiffer, Arno, Inc, Greenbush, WI. by conversation on February 5, 2007.

 

Firm initiated recall is ongoing.

 

REASON

 

Blood meal used to make cattle feed was recalled because it was cross- contaminated with prohibited bovine meat and bone meal that had been manufactured on common equipment and labeling did not bear cautionary BSE statement.

 

VOLUME OF PRODUCT IN COMMERCE

 

42,090 lbs.

 

DISTRIBUTION

 

WI

 

___________________________________

 

PRODUCT

 

Custom dairy premix products: MNM ALL PURPOSE Pellet, HILLSIDE/CDL Prot- Buffer Meal, LEE, M.-CLOSE UP PX Pellet, HIGH DESERT/ GHC LACT Meal, TATARKA, M CUST PROT Meal, SUNRIDGE/CDL PROTEIN Blend, LOURENZO, K PVM DAIRY Meal, DOUBLE B DAIRY/GHC LAC Mineral, WEST PIONT/GHC CLOSEUP Mineral, WEST POINT/GHC LACT Meal, JENKS, J/COMPASS PROTEIN Meal, COPPINI - 8# SPECIAL DAIRY Mix, GULICK, L-LACT Meal (Bulk), TRIPLE J - PROTEIN/LACTATION, ROCK CREEK/GHC MILK Mineral, BETTENCOURT/GHC S.SIDE MK-MN, BETTENCOURT #1/GHC MILK MINR, V&C DAIRY/GHC LACT Meal, VEENSTRA, F/GHC LACT Meal, SMUTNY, A- BYPASS ML W/SMARTA, Recall # V-025-2007

 

CODE

 

The firm does not utilize a code - only shipping documentation with commodity and weights identified.

 

RECALLING FIRM/MANUFACTURER

 

Rangen, Inc, Buhl, ID, by letters on February 13 and 14, 2007. Firm initiated recall is complete.

 

REASON

 

Products manufactured from bulk feed containing blood meal that was cross contaminated with prohibited meat and bone meal and the labeling did not bear cautionary BSE statement.

 

VOLUME OF PRODUCT IN COMMERCE

 

9,997,976 lbs.

 

DISTRIBUTION

 

ID and NV

 

END OF ENFORCEMENT REPORT FOR MARCH 21, 2007

 


 

2013

 

Sunday, December 15, 2013

 

FDA PART 589 -- SUBSTANCES PROHIBITED FROM USE IN ANIMAL FOOD OR FEED VIOLATIONS OFFICIAL ACTION INDICATED OIA UPDATE DECEMBER 2013 UPDATE

 


 

Tuesday, December 23, 2014

 

FDA PART 589 -- SUBSTANCES PROHIBITED FROM USE IN ANIMAL FOOD OR FEED VIOLATIONS OFFICIAL ACTION INDICATED OAI UPDATE DECEMBER 2014 BSE TSE PRION

 


 

Thursday, July 24, 2014

 

*** Protocol for further laboratory investigations into the distribution of infectivity of Atypical BSE SCIENTIFIC REPORT OF EFSA

 


 

Saturday, June 12, 2010

 

PUBLICATION REQUEST AND FOIA REQUEST Project Number: 3625-32000-086-05 Study of Atypical Bse

 


 

Sunday, December 28, 2014

 

Reverse Freedom of Information Act request rFOIA FSIS USDA APHIS TSE PRION aka BSE MAD COW TYPE DISEASE December 2014

 


 

Tuesday, August 12, 2014

 

MAD COW USDA TSE PRION COVER UP or JUST IGNORANCE, for the record AUGUST 2014

 


 

Thursday, October 02, 2014

 

[Docket No. APHIS-2013-0064] Concurrence With OIE Risk Designations for Bovine Spongiform Encephalopathy

 


 

Saturday, August 14, 2010

 

BSE Case Associated with Prion Protein Gene Mutation (g-h-BSEalabama) and VPSPr PRIONPATHY

 


 

2009 UPDATE ON ALABAMA AND TEXAS MAD COWS 2005 and 2006

 


 

snip...see full text ;

 

Monday, February 23, 2015

 

20th BSE Case Raises New Concerns about Canada's Feeding Practices and Voluntary Testing Program; Highlights Importance of COOL

 


 

Tuesday, February 17, 2015

 

Could we spot the next BSE?, asks BVA President

 


 


 


 


 

 

TSS

 
 
 

American Association of Zoo Veterinarians Infectious Disease Committee Manual 2013

 

BOVINE SPONGIFORM ENCEPHALOPATHY (BSE)

 

Little is known about atypical BSE. The origin and natural routes of transmission, if any, have yet to be determined. Almost all cases have been in older cattle (usually > 8 years of age) that have shown little resemblance to the clinic-pathological picture seen in classical disease. It has been suggested that the disease may be sporadic or be caused by a genetic mutation, but no convincing evidence has been found to support either of these ideas. The correct answer will probably only come by study of the future annual incidence curves of both types of disease. Regardless of the origin of atypical BSE, the possibility of recycling the disease in cattle and other ruminants, as well as the potential for transmission to humans, mandate a continuation of feed and specified-risk materials (SRM) bans, together with diagnostic testing programs for some time to come.

 

snip...

 

Naturally occurring cases of BSE in species other than cattle have been very limited and have been linked to exposure to contaminated feed or infected carcasses. The majority of cases originated in the UK and like BSE in cattle, have declined with the implementation of feed controls. None of the exotic animals were infected in the wild.

 

Experts who may be consulted: Linda A. Detwiler, DVM Clinical Professor Department of Pathobiology and Population Medicine

 

College of Veterinary Medicine Mississippi State University 732-580-9391 Fax: 732-741-7751 ldetwiler@belle-terre.com

 


 

Atypical BSE: Transmissibility

 

 BASE (L) transmitted to:  cattle (IC) - inc < 20 mos and oral?)

 

 Cynomolgus macaques (IC)

 

 Mouse lemurs (IC and oral)

 

 wild-type mice (IC)

 

 bovinized transgenic mice (IC and IP)

 

 humanized transgenic mice (IC)

 

 H cases transmitted to:

 

 cattle – IC incubations < 20 months

 

 bovinized transgenic mice (IC)

 

 ovinized transgenic mice (IC)

 

 C57BL mice (IC)

 

 One study did not transmit to humanized PrP Met 129 mice

 

Evaluation of Possibility of Atypical

 

BSE Transmitting to Humans

 

 Possble interpretation:

 

 L type seems to transmit to nonhuman primates with greater ease than classical BSE

 

 L type also transmitted to humanized transgenic mice with higher attack rate and shorter incubation period than classical?

 

 H type did not transmit to Tg Hu transgenic mice

 

Linda Detwiller, 5/10/2011

 


 

I ask Professor Kong ;

 

Thursday, December 04, 2008 3:37 PM

 

Subject: RE: re--Chronic Wating Disease (CWD) and Bovine Spongiform Encephalopathies (BSE): Public Health Risk Assessment

 

IS the h-BSE more virulent than typical BSE as well, or the same as cBSE, or less virulent than cBSE? just curious.....

 

Professor Kong reply ;

 

.....snip

 

As to the H-BSE, we do not have sufficient data to say one way or another, but we have found that H-BSE can infect humans. I hope we could publish these data once the study is complete. Thanks for your interest.

 

Best regards, Qingzhong Kong, PhD Associate Professor Department of Pathology Case Western Reserve University Cleveland, OH 44106 USA

 

BSE-H is also transmissible in our humanized Tg mice. The possibility of more than two atypical BSE strains will be discussed.

 

Supported by NINDS NS052319, NIA AG14359, and NIH AI 77774.

 


 


 

P.4.23 Transmission of atypical BSE in humanized mouse models

 

Liuting Qing1, Wenquan Zou1, Cristina Casalone2, Martin Groschup3, Miroslaw Polak4, Maria Caramelli2, Pierluigi Gambetti1, Juergen Richt5, Qingzhong Kong1 1Case Western Reserve University, USA; 2Instituto Zooprofilattico Sperimentale, Italy; 3Friedrich-Loeffler-Institut, Germany; 4National Veterinary Research Institute, Poland; 5Kansas State University (Previously at USDA National Animal Disease Center), USA

 

Background: Classical BSE is a world-wide prion disease in cattle, and the classical BSE strain (BSE-C) has led to over 200 cases of clinical human infection (variant CJD). Atypical BSE cases have been discovered in three continents since 2004; they include the L-type (also named BASE), the H-type, and the first reported case of naturally occurring BSE with mutated bovine PRNP (termed BSE-M). The public health risks posed by atypical BSE were argely undefined.

 

Objectives: To investigate these atypical BSE types in terms of their transmissibility and phenotypes in humanized mice.

 

Methods: Transgenic mice expressing human PrP were inoculated with several classical (C-type) and atypical (L-, H-, or Mtype) BSE isolates, and the transmission rate, incubation time, characteristics and distribution of PrPSc, symptoms, and histopathology were or will be examined and compared.

 

Results: Sixty percent of BASE-inoculated humanized mice became infected with minimal spongiosis and an average incubation time of 20-22 months, whereas only one of the C-type BSE-inoculated mice developed prion disease after more than 2 years. Protease-resistant PrPSc in BASE-infected humanized Tg mouse brains was biochemically different from bovine BASE or sCJD. PrPSc was also detected in the spleen of 22% of BASE-infected humanized mice, but not in those infected with sCJD. Secondary transmission of BASE in the humanized mice led to a small reduction in incubation time. The atypical BSE-H strain is also transmissible with distinct phenotypes in the humanized mice, but no BSE-M transmission has been observed so far.

 

Discussion: Our results demonstrate that BASE is more virulent than classical BSE, has a lymphotropic phenotype, and displays a modest transmission barrier in our humanized mice. BSE-H is also transmissible in our humanized Tg mice. The possibility of more than two atypical BSE strains will be discussed.

 

Supported by NINDS NS052319, NIA AG14359, and NIH AI 77774.

 


 


 


 

14th International Congress on Infectious Diseases H-type and L-type Atypical BSE January 2010 (special pre-congress edition)

 

18.173 page 189

 

Experimental Challenge of Cattle with H-type and L-type Atypical BSE

 

A. Buschmann1, U. Ziegler1, M. Keller1, R. Rogers2, B. Hills3, M.H. Groschup1. 1Friedrich-Loeffler-Institut, Greifswald-Insel Riems, Germany, 2Health Canada, Bureau of Microbial Hazards, Health Products & Food Branch, Ottawa, Canada, 3Health Canada, Transmissible Spongiform Encephalopathy Secretariat, Ottawa, Canada

 

Background: After the detection of two novel BSE forms designated H-type and L-type atypical BSE the question of the pathogenesis and the agent distribution of these two types in cattle was fully open. From initial studies of the brain pathology, it was already known that the anatomical distribution of L-type BSE differs from that of the classical type where the obex region in the brainstem always displays the highest PrPSc concentrations. In contrast in L-type BSE cases, the thalamus and frontal cortex regions showed the highest levels of the pathological prion protein, while the obex region was only weakly involved.

 

Methods:We performed intracranial inoculations of cattle (five and six per group) using 10%brainstemhomogenates of the two German H- and L-type atypical BSE isolates. The animals were inoculated under narcosis and then kept in a free-ranging stable under appropriate biosafety conditions. At least one animal per group was killed and sectioned in the preclinical stage and the remaining animals were kept until they developed clinical symptoms. The animals were examined for behavioural changes every four weeks throughout the experiment following a protocol that had been established during earlier BSE pathogenesis studies with classical BSE.

 

Results and Discussion: All animals of both groups developed clinical symptoms and had to be euthanized within 16 months. The clinical picture differed from that of classical BSE, as the earliest signs of illness were loss of body weight and depression. However, the animals later developed hind limb ataxia and hyperesthesia predominantly and the head. Analysis of brain samples from these animals confirmed the BSE infection and the atypical Western blot profile was maintained in all animals. Samples from these animals are now being examined in order to be able to describe the pathoge esis and agent distribution for these novel BSE types.

 

Conclusions: A pilot study using a commercially avaialble BSE rapid test ELISA revealed an essential restriction of PrPSc to the central nervous system for both atypical BSE forms. A much more detailed analysis for PrPSc and infectivity is still ongoing.

 


 

14th ICID International Scientific Exchange Brochure - Final Abstract Number: ISE.114

 

Session: International Scientific Exchange

 

Transmissible Spongiform encephalopathy (TSE) animal and human TSE in North America update October 2009

 

T. Singeltary Bacliff, TX, USA

 

Background: An update on atypical BSE and other TSE in North America. Please remember, the typical U.K. c-BSE, the atypical l-BSE (BASE), and h-BSE have all been documented in North America, along with the typical scrapie's, and atypical Nor-98 Scrapie, and to date, 2 different strains of CWD, and also TME. All these TSE in different species have been rendered and fed to food producing animals for humans and animals in North America (TSE in cats and dogs ?), and that the trading of these TSEs via animals and products via the USA and Canada has been immense over the years, decades.

 

Methods: 12 years independent research of available data

 

Results: I propose that the current diagnostic criteria for human TSEs only enhances and helps the spreading of human TSE from the continued belief of the UKBSEnvCJD only theory in 2009. With all the science to date refuting it, to continue to validate this old myth, will only spread this TSE agent through a multitude of potential routes and sources i.e. consumption, medical i.e., surgical, blood, dental, endoscopy, optical, nutritional supplements, cosmetics etc.

 

Conclusion: I would like to submit a review of past CJD surveillance in the USA, and the urgent need to make all human TSE in the USA a reportable disease, in every state, of every age group, and to make this mandatory immediately without further delay. The ramifications of not doing so will only allow this agent to spread further in the medical, dental, surgical arena's. Restricting the reporting of CJD and or any human TSE is NOT scientific. Iatrogenic CJD knows NO age group, TSE knows no boundaries. I propose as with Aguzzi, Asante, Collinge, Caughey, Deslys, Dormont, Gibbs, Gajdusek, Ironside, Manuelidis, Marsh, et al and many more, that the world of TSE Transmissible Spongiform Encephalopathy is far from an exact science, but there is enough proven science to date that this myth should be put to rest once and for all, and that we move forward with a new classification for human and animal TSE that would properly identify the infected species, the source species, and then the route.

 


 

snip... see more breaches in the BSE aka mad cow Triple Firewall, that never was here ;

 

Friday, January 23, 2015

 

*** Replacement of soybean meal in compound feed by European protein sources and relaxing the mad cow ban $

 


 

Comment from Terry Singeltary Sr. This is a Comment on the Animal and Plant Health Inspection Service (APHIS) Notice: Agency Information Collection Activities; Proposals, Submissions, and Approvals: Bovine Spongiform Encephalopathy; Importation of Animals and Animal Products

 

For related information, Open Docket Folder Docket folder icon

 

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Comment View document:Docket No. APHIS-2014-0107 Bovine Spongiform Encephalopathy; Importation of Animals and Animal Products Singeltary Submission ;

 

I believe that there is more risk to the world from Transmissible Spongiform Encephalopathy TSE prion aka mad cow type disease now, coming from the United States and all of North America, than there is risk coming to the USA and North America, from other Countries. I am NOT saying I dont think there is any risk for the BSE type TSE prion coming from other Countries, I am just saying that in 2015, why is the APHIS/USDA/FSIS/FDA still ignoring these present mad cow risk factors in North America like they are not here?

 

North America has more strains of TSE prion disease, in more species (excluding zoo animals in the early BSE days, and excluding the Feline TSE and or Canine TSE, because they dont look, and yes, there has been documented evidence and scientific studies, and DEFRA Hound study, that shows the canine spongiform encephalopathy is very possible, if it has not already happened, just not documented), then any other Country in the world. Mink TME, Deer Elk cervid CWD (multiple strains), cBSE cattle, atypical L-type BSE cattle, atypical H-type BSE cattle, atyical HG type BSE cow (the only cow documented in the world to date with this strain), typical sheep goat Scrapie (multiple strains), and the atypical Nor-98 Scrapie, which has been linked to sporadic CJD, Nor-98 atypical Scrapie has spread from coast to coast. sporadic CJD on the rise, with different strains mounting, victims becoming younger, with the latest nvCJD human mad cow case being documented in Texas again, this case, NOT LINKED TO EUROPEAN TRAVEL CDC.

 

typical BSE can propagate as nvCJD and or sporadic CJD (Collinge et al), and sporadic CJD has now been linked to atypical BSE, Scrapie and atypical Scrapie, and scientist are very concerned with CWD TSE prion in the Cervid populations. in my opinion, the BSE MRR policy, which overtook the BSE GBR risk assessments for each country, and then made BSE confirmed countries legal to trade mad cow disease, which was all brought forth AFTER that fateful day December 23, 2003, when the USA lost its gold card i.e. BSE FREE status, thats the day it all started. once the BSE MRR policy was shoved down every countries throat by USDA inc and the OIE, then the legal trading of Scrapie was validated to be a legal trading commodity, also shoved through by the USDA inc and the OIE, the world then lost 30 years of attempted eradication of the BSE TSE prion disease typical and atypical strains, and the BSE TSE Prion aka mad cow type disease was thus made a legal trading commodity, like it or not. its all about money now folks, trade, to hell with human health with a slow incubating disease, that is 100% fatal once clinical, and forget the fact of exposure, sub-clinical infection, and friendly fire there from i.e. iatrogenic TSE prion disease, the pass it forward mode of the TSE PRION aka mad cow type disease. its all going to be sporadic CJD or sporadic ffi, or sporadic gss, or now the infamous VPSPr. ...problem solved $$$

 

the USDA/APHIS/FSIS/FDA triple mad cow BSE firewall, well, that was nothing but ink on paper.

 

for this very reason I believe the BSE MRR policy is a total failure, and that this policy should be immediately withdrawn, and set back in place the BSE GBR Risk Assessments, with the BSE GBR risk assessments set up to monitor all TSE PRION disease in all species of animals, and that the BSE GBR risk assessments be made stronger than before.

 

lets start with the recent notice that beef from Ireland will be coming to America.

 

Ireland confirmed around 1655 cases of mad cow disease. with the highest year confirming about 333 cases in 2002, with numbers of BSE confirmed cases dropping from that point on, to a documentation of 1 confirmed case in 2013, to date. a drastic decrease in the feeding of cows to cows i.e. the ruminant mad cow feed ban, and the enforcement of that ban, has drastically reduced the number of BSE cases in Europe, minus a few BABs or BARBs. a far cry from the USDA FDA triple BSE firewall, which was nothing more than ink on paper, where in 2007, in one week recall alone, some 10 MILLION POUNDS OF BANNED POTENTIAL MAD COW FEED WENT OUT INTO COMMERCE IN THE USA. this is 10 years post feed ban. in my honest opinion, due to the blatant cover up of BSE TSE prion aka mad cow disease in the USA, we still have no clue as to the true number of cases of BSE mad cow disease in the USA or North America as a whole. ...just saying.

 

Number of reported cases of bovine spongiform encephalopathy (BSE) in farmed cattle worldwide* (excluding the United Kingdom)

 

Country/Year

 

snip...please see attached pdf file, with references of breaches in the USA triple BSE mad cow firewalls, and recent science on the TSE prion disease. ...TSS No documents available. AttachmentsView All (1) Empty Docket No. APHIS-2014-0107 Bovine Spongiform Encephalopathy; Importation of Animals and Animal Products Singeltary Submission View Attachment:

 


 

Sunday, January 11, 2015

 

Docket No. APHIS-2014-0107 Bovine Spongiform Encephalopathy; Importation of Animals and Animal Products Singeltary Submission

 


 


 

Friday, January 23, 2015

 

*** Replacement of soybean meal in compound feed by European protein sources and relaxing the mad cow ban $

 


 

Saturday, January 24, 2015

 

*** Bovine Spongiform Encephalopathy: Atypical Pros and Cons

 


 

Monday, December 1, 2014

 

Germany Bovine Spongiform Encephalopathy BSE CJD TSE Prion disease A Review December 1, 2014

 


 

Thursday, January 29, 2015

 

Identification of H-type BSE in Portugal

 


 

TSS