Abstract: Embodiments of the present invention provide a system for securely authenticating users using quantum key distribution protocol. The system is configured for receiving an authentication request comprising at least one credential from a user, via a user device, calculating an authentication match score for the at least one credential, retrieving an authentication token associated with the user stored on an external physical device connected to the user device, retrieving an enrollment match score associated with the authentication token of the user, validating the at least one credential by comparing the authentication match score of the at least one credential with the enrollment match score associated with the user, determining that the validation is not successful, and performing a quantum key distribution secret verification based on an enrollment common base stored on a quantum computing platform during the enrollment phase via a quantum communication network.

Abstract: A method is provided for distinguishing between and/or diagnosing Parkinson's disease (PD) or multiple system atrophy (MSA) in a subject who is exhibiting symptoms associated with both PD and MSA. The method comprises: (A) contacting a biological sample obtained from the subject and comprising soluble, misfolded alpha-synuclein (?S) protein with a pre-incubation mixture comprising a monomeric ?S substrate and an indicator to form an incubation mixture; (B) conducting an incubation cycle two or more times on the incubation mixture to form misfolded ?S aggregates; (C) subjecting the incubation mixture to excitation and detecting via indicator fluorescence emission the misfolded ?S aggregates; and (D) diagnosing the subject has having PD or MSA depending on the fluorescence emission intensity. In some aspects, the incubation cycles are conducted in the presence of a bead.

Abstract: Methods and kits are provided for amplifying and detecting ?S proteins from samples, for example, from patients having Parkinson's Disease. For example, a method for determining a presence of a soluble, misfolded ?S protein may include: contacting the sample with a monomeric, folded ?S protein to form an incubation mixture; conducting an incubation cycle two or more times on the incubation mixture effective to form an amplified portion of misfolded ?S protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded ?S protein in the presence of the soluble, misfolded ?S protein; physically disrupting the incubation mixture effective to at least partly de-aggregate at least a portion of a misfolded ?S aggregate present; and determining the presence of the soluble, misfolded ?S protein in the sample by detecting at least a portion of the soluble, misfolded ?S protein.

Abstract: Methods and kits are provided for amplifying and detecting misfolded tau protein from samples, for example, from patients having tauopathies such as Alzheimer's Disease, Progressive Supranuclear Palsy, and the like.

Abstract: Methods and kits are provided for amplifying and detecting misfolded tau protein from samples, for example, from patients having tauopathies such as Alzheimer's Disease, Progressive Supranuclear Palsy, and the like.

Abstract: A method is provided for distinguishing between and/or diagnosing Parkinson's disease (PD) or multiple system atrophy (MSA) in a subject who is exhibiting symptoms associated with both PD and MSA. The method comprises: (A) contacting a biological sample obtained from the subject and comprising soluble, misfolded alpha-synuclein (?S) protein with a pre-incubation mixture comprising a monomeric ?S substrate and an indicator to form an incubation mixture; (B) conducting an incubation cycle two or more times on the incubation mixture to form misfolded ?S aggregates; (C) subjecting the incubation mixture to excitation and detecting via indicator fluorescence emission the misfolded ?S aggregates; and (D) diagnosing the subject has having PD or MSA depending on the fluorescence emission intensity. In some aspects, the incubation cycles are conducted in the presence of a bead.

Abstract: Methods and kits are provided for amplifying and detecting ?S proteins from samples, for example, from patients having Parkinson's Disease. For example, a method for determining a presence of a soluble, misfolded ?S protein may include: contacting the sample with a monomeric, folded ?S protein to form an incubation mixture; conducting an incubation cycle two or more times on the incubation mixture effective to form an amplified portion of misfolded ?S protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded ?S protein in the presence of the soluble, misfolded ?S protein; physically disrupting the incubation mixture effective to at least partly de-aggregate at least a portion of a misfolded ?S aggregate present; and determining the presence of the soluble, misfolded ?S protein in the sample by detecting at least a portion of the soluble, misfolded ?S protein.

Abstract: A method is provided for distinguishing between and/or diagnosing Parkinson's disease (PD) or multiple system atrophy (MSA) in a subject who is exhibiting symptoms associated with both PD and MSA. The method comprises: (A) contacting a biological sample obtained from the subject and comprising soluble, misfolded alpha-synuclein (?S) protein with a pre-incubation mixture comprising a monomeric ?S substrate and an indicator to form an incubation mixture; (B) conducting an incubation cycle two or more times on the incubation mixture to form misfolded ?S aggregates; (C) subjecting the incubation mixture to excitation and detecting via indicator fluorescence emission the misfolded ?S aggregates; and (D) diagnosing the subject has having PD or MSA depending on the fluorescence emission intensity. In some aspects, the incubation cycles are conducted in the presence of a bead.

Abstract: Methods and kits are provided for amplifying and detecting ?S proteins from samples, for example, from patients having Parkinson's Disease. For example, a method for determining a presence of a soluble, misfolded ?S protein may include: contacting the sample with a monomeric, folded ?S protein to form an incubation mixture; conducting an incubation cycle two or more times on the incubation mixture effective to form an amplified portion of misfolded ?S protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded ?S protein in the presence of the soluble, misfolded ?S protein; physically disrupting the incubation mixture effective to at least partly de-aggregate at least a portion of a misfolded ?S aggregate present; and determining the presence of the soluble, misfolded ?S protein in the sample by detecting at least a portion of the soluble, misfolded ?S protein.

Abstract: Methods and kits are provided for amplifying and detecting misfolded proteins from samples, for example, from patients having Alzheimer's Disease, Parkinson's Disease, and the like. For example, a method for determining a presence of soluble, misfolded protein in a sample may include contacting the sample with a monomeric, folded protein to form an incubation mixture; conducting an incubation cycle two or more times effective to form an amplified portion of misfolded protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded protein; physically disrupting the incubation mixture effective to break up at least a portion of any protein aggregate present; and determining the presence of the soluble, misfolded protein in the sample by detecting at least a portion of the soluble, misfolded protein. The monomeric, folded protein and the soluble, misfolded protein may exclude prion protein (PrP) and isoforms thereof.

Abstract: Methods and kits are provided for amplifying and detecting misfolded tau protein from samples, for example, from patients having tauopathies such as Alzheimer's Disease, Progressive Supranuclear Palsy, and the like.

Abstract: Methods and kits are provided for amplifying and detecting misfolded proteins from samples, for example, from patients having Alzheimer's Disease, Parkinson's Disease, and the like. For example, a method for determining a presence of soluble, misfolded protein in a sample may include contacting the sample with a monomeric, folded protein to form an incubation mixture; conducting an incubation cycle two or more times effective to form an amplified portion of misfolded protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded protein; physically disrupting the incubation mixture effective to break up at least a portion of any protein aggregate present; and determining the presence of the soluble, misfolded protein in the sample by detecting at least a portion of the soluble, misfolded protein. The monomeric, folded protein and the soluble, misfolded protein may exclude prion protein (PrP) and isoforms thereof.

Abstract: Methods and kits are provided for amplifying and detecting A? proteins from samples, for example, from patients having Alzheimer's Disease. For example, a method for determining a presence of a soluble, misfolded A? protein may include contacting the sample with a monomeric, folded A? protein to form an incubation mixture; conducting an incubation cycle two or more times on the incubation mixture effective to form an amplified portion of misfolded A? protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded A? protein; physically disrupting the incubation mixture effective to at least partly de-aggregate at least a portion of a misfolded A? aggregate present; and determining the presence of the soluble, misfolded A? protein in the sample by detecting at least a portion of the amplified portion of misfolded A? protein.

Abstract: Methods and kits are provided for amplifying and detecting A? proteins from samples, for example, from patients having Alzheimer's Disease. For example, a method for determining a presence of a soluble, misfolded A? protein may include contacting the sample with a monomeric, folded A? protein to form an incubation mixture; conducting an incubation cycle two or more times on the incubation mixture effective to form an amplified portion of misfolded A? protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded A? protein; physically disrupting the incubation mixture effective to at least partly de-aggregate at least a portion of a misfolded A? aggregate present; and determining the presence of the soluble, misfolded A? protein in the sample by detecting at least a portion of the amplified portion of misfolded A? protein.

Abstract: Methods and kits are provided for amplifying and detecting misfolded proteins from samples, for example, from patients having Alzheimer's Disease, Parkinson's Disease, and the like. For example, a method for determining a presence of soluble, misfolded protein in a sample may include contacting the sample with a monomeric, folded protein to form an incubation mixture; conducting an incubation cycle two or more times effective to form an amplified portion of misfolded protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded protein; physically disrupting the incubation mixture effective to break up at least a portion of any protein aggregate present; and determining the presence of the soluble, misfolded protein in the sample by detecting at least a portion of the soluble, misfolded protein. The monomeric, folded protein and the soluble, misfolded protein may exclude prion protein (PrP) and isoforms thereof.

Abstract: Methods and kits are provided for amplifying and detecting A? proteins from samples, for example, from patients having Alzheimer's Disease. For example, a method for determining a presence of a soluble, misfolded A? protein may include contacting the sample with a monomeric, folded A? protein to form an incubation mixture; conducting an incubation cycle two or more times on the incubation mixture effective to form an amplified portion of misfolded A? protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded A? protein; physically disrupting the incubation mixture effective to at least partly de-aggregate at least a portion of a misfolded A? aggregate present; and determining the presence of the soluble, misfolded A? protein in the sample by detecting at least a portion of the amplified portion of misfolded A? protein.

Abstract: Methods and kits are provided for amplifying and detecting ?S proteins from samples, for example, from patients having Parkinson's Disease. For example, a method for determining a presence of a soluble, misfolded ?S protein may include: contacting the sample with a monomeric, folded ?S protein to form an incubation mixture; conducting an incubation cycle two or more times on the incubation mixture effective to form an amplified portion of misfolded ?S protein; incubating the incubation mixture effective to cause misfolding and/or aggregation of at least a portion of the monomeric, folded ?S protein in the presence of the soluble, misfolded ?S protein; physically disrupting the incubation mixture effective to at least partly de-aggregate at least a portion of a misfolded ?S aggregate present; and determining the presence of the soluble, misfolded ?S protein in the sample by detecting at least a portion of the soluble, misfolded ?S protein.

Abstract: A novel chimeric protein of rabies virus designed to express a chimeric G protein at a high level in transgenic plants. A gene was also designed and chemically synthesised to encode the chimeric G protein and expressed at high level in plant tissue. The gene was expressed in transgenic tobacco plants to examine its therapeutic efficacy against infection by rabies virus. The chimeric G protein was enriched in plant membranes. The BalbC mice were immunised with the plant leaf expressed G-protein. Plant derived chimeric G protein elicited higher immune response as compared to the commercial vaccine. The mice displayed protective immunity when they were challenged with live virus. Chimeric G protein expressed at high level in plant leaves was demonstrated to function as a commercially valuable subunit vaccine against rabies virus infection.