The present snack-type food product with high hypoproteic content comprises proteins of high biological value (HBV), in which the principal macronutrients are protein, sugars, carbohydrates and fats. This snack-type food product was specifically developed for patients undergoing haemodialysis treatment. The snack-type food product has sensory characteristics that allow it to achieve better acceptance in comparison with other products available on the market.

The present snack-type food product with high hypoproteic content comprises proteins of high biological value (HBV), in which the principal macronutrients are protein, sugars, carbohydrates and fats. This snack-type food product was specifically developed for patients undergoing haemodialysis treatment. The snack-type food product has sensory characteristics that allow it to achieve better acceptance in comparison with other products available on the market.

Provided are methods and compositions for maintaining the viability of photoreceptor cells following retinal detachment. The viability of photoreceptor cells can be preserved by administering an apoptosis inhibitor to a mammal having an eye with retinal detachment. The apoptosis inhibitor maintains the viability of the photoreceptor cells until such time that the retina becomes reattached to the underlying retinal pigment epithelium and choroid. The treatment minimizes the loss of vision, which otherwise may occur as a result of retinal detachment.

Provided are methods and compositions for maintaining the viability of photoreceptor cells following retinal detachment. The viability of photoreceptor cells can be preserved by administering an apoptosis inhibitor to a mammal having an eye with retinal detachment. The apoptosis inhibitor maintains the viability of the photoreceptor cells until such time that the retina becomes reattached to the underlying retinal pigment epithelium and choroid. The treatment minimizes the loss of vision, which otherwise may occur as a result of retinal detachment.

The present invention provides a method for treating a human subject afflicted with multiple sclerosis or a single clinical attack consistent with multiple sclerosis with a pharmaceutical composition comprising glatiramer acetate and a pharmaceutically acceptable carrier, comprising the steps of: (i) determining a genotype of the subject at a location corresponding to the location of one or more single nucleotide polymorphisms (SNPs) selected from the group consisting of: Group 1, (ii) identifying the subject as a predicted responder to glatiramer acetate if the genotype of the subject contains one or more A alleles at the location of Group 2, one or more C alleles at the location of Group 3, one or more G alleles at the location of Group 4, or one or more T alleles at the location of kgp18432055, kgp279772, kgp3991733 or kgp7242489; and (iii) administering the pharmaceutical composition comprising glatiramer acetate and a pharmaceutically acceptable carrier to the subject only if the subject is identified as a predicted responder to glatiramer acetate.

The patent provides a process of preparing a pharmaceutical preparation of glatiramer acetate and mannitol in a suitable container comprising the steps of: (i) obtaining an aqueous pharmaceutical solution of glatiramer acetate and mannitol; (ii) filtering the aqueous pharmaceutical solution at a temperature of from above 0° C. up to 17.5° C. to produce a filtrate; and (iii) filling the suitable container with the filtrate obtained after performing step (ii), so as to thereby prepare the pharmaceutical preparation of glatiramer acetate and mannitol in the suitable container.

This patent further provides an aqueous pharmaceutical solution comprising 40 mg/ml glatiramer acetate and 40 mg/ml mannitol, wherein the aqueous pharmaceutical solution a) has a viscosity in the range of 2.0-3.5 cPa; or b) has an osmolality in the range of 275-325 mosmol/Kg.

This patent also provides a prefilled syringe, an automated injector and a method of treatment of a human patient.

The patent provides a process of preparing a pharmaceutical preparation of glatiramer acetate and mannitol in a suitable container comprising the steps of: (i) obtaining an aqueous pharmaceutical solution of glatiramer acetate and mannitol; (ii) filtering the aqueous pharmaceutical solution at a temperature of from above 0° C. up to 17.5° C. to produce a filtrate; and (iii) filling the suitable container with the filtrate obtained after performing step (ii), so as to thereby prepare the pharmaceutical preparation of glatiramer acetate and mannitol in the suitable container.

This patent further provides an aqueous pharmaceutical solution comprising 40 mg/ml glatiramer acetate and 40 mg/ml mannitol, wherein the aqueous pharmaceutical solution a) has a viscosity in the range of 2.0-3.5 cPa; or b) has an osmolality in the range of 275-325 mosmol/Kg.

This patent also provides a prefilled syringe, an automated injector and a method of treatment of a human patient.

Described herein are variants of alpha-hemolysin having at least one amino acid substitution at H35G, E111N, M113A, and/or K147N in the mature, wild-type alpha-hemolysin amino acid sequence. In certain examples, the variant may have a substitution at E111S, M113S, T145S, K147S, or L135I in the mature alpha-hemolysin amino acid sequence. The α-hemolysin variants may also include a substitution at H144A and/or a series of glycine residues spanning residues 127 to 131 of the mature, wild-type alpha hemolysin. Also provided are nanopore assemblies including the alpha-hemolysin variants, the assembly having an increased nanopore lifetime. Further, provided are variants that, in addition to providing increased lifetime, provide a decreased time-to-thread. Hence, the variants provided herein both increase nanopore lifetime and improve efficiency and accuracy of DNA sequencing reactions using nanopores comprising the variants.

Described herein are variants of alpha-hemolysin having at least one amino acid substitution at H35G, E111N, M113A, and/or K147N in the mature, wild-type alpha-hemolysin amino acid sequence. In certain examples, the variant may have a substitution at E111S, M113S, T145S, K147S, or L135I in the mature alpha-hemolysin amino acid sequence. The α-hemolysin variants may also include a substitution at H144A and/or a series of glycine residues spanning residues 127 to 131 of the mature, wild-type alpha hemolysin. Also provided are nanopore assemblies including the alpha-hemolysin variants, the assembly having an increased nanopore lifetime. Further, provided are variants that, in addition to providing increased lifetime, provide a decreased time-to-thread. Hence, the variants provided herein both increase nanopore lifetime and improve efficiency and accuracy of DNA sequencing reactions using nanopores comprising the variants.

A lactic acid bacterium-containing composition including a lactic acid bacterium having a human papillomavirus (HPV) E7 protein-derived polypeptide on a surface thereof, wherein the HPV E7 protein-derived polypeptide is included in an amount of 0.03 μg to 1.0 μg per 1×10.sup.8 lactic acid bacteria; a therapeutic oral pharmaceutical composition for at least one of an HPV infectious disease and an HPV-associated tumor which includes the lactic acid bacterium-containing composition; and a mucosal immunity-inducing agent which includes the lactic acid bacterium-containing composition.