Abstract: Disclosed herein are nanoparticles and method for manufacturing the same. The nanoparticle is essentially composed of albumin and polyethylene glycol, wherein the albumin is covalently crosslinked with the polyethylene glycol.

Abstract: The invention relates to a kit for preparation of target radiopharmaceuticals, a method of using the kit to prepare target radiopharmaceuticals and use of the target radiopharmaceuticals. The target radiopharmaceuticals comprise a radio-nuclear loading on liposome and inhibit the tumor growth and metastatic progression of head and neck cancer, lung cancer and brain cancer. The radiopharmaceuticals may be used for treating the mentioned cancers.

Abstract: An automated test apparatus for risk and integrity testing for pharmaceutical filtration membranes, including at least the following components: a liquid injection inlet, a pump, a fluid pressure gauge, a gas pressure gauge, a plurality of solenoid valves, a plurality of membranes, a gas pressure regulator valve, a pharmaceutical product bottle, and a bubble generation bottle. The automated test apparatus of the present invention is controlled by computer software in connection with an automatic pharmaceutical synthesis apparatus for automated testing. In use of the automated test apparatus of the present invention, it needs only to start the operating system of the automated test apparatus for membrane risk and integrity test after the completion of the automatic pharmaceutical synthesis. The membrane risk and integrity test can be accomplished in a short time by measuring pressures of gas and liquid with pressure gauges deposed online concurrently.

Abstract: Disclosed herein are nanoparticles and method for manufacturing the same. The nanoparticle is essentially composed of albumin and polyethylene glycol, wherein the albumin is covalently crosslinked with the polyethylene glycol.

Abstract: The invention relates to a kit for preparation of target radiopharmaceuticals, a method of using the kit to prepare target radiopharmaceuticals and use of the target radiopharmaceuticals. The target radiopharmaceuticals comprise a radio-nuclear loading on liposome and inhibit the tumor growth and metastatic progression of head and neck cancer, lung cancer and brain cancer. The radiopharmaceuticals may be used for treating the mentioned cancers.

Abstract: An automated test apparatus for risk and integrity testing for pharmaceutical filtration membranes, including at least the following components: a liquid injection inlet, a pump, a fluid pressure gauge, a gas pressure gauge, a plurality of solenoid valves, a plurality of membranes, a gas pressure regulator valve, a pharmaceutical product bottle, and a bubble generation bottle. The automated test apparatus of the present invention is controlled by computer software in connection with an automatic pharmaceutical synthesis apparatus for automated testing. In use of the automated test apparatus of the present invention, it needs only to start the operating system of the automated test apparatus for membrane risk and integrity test after the completion of the automatic pharmaceutical synthesis. The membrane risk and integrity test can be accomplished in a short time by measuring pressures of gas and liquid with pressure gauges deposed online concurrently.

Abstract: An automated synthesis device to produce Re-188-BMEDA solution including: a plurality of reagent vials, three-way solenoid valves, gel filtration columns and micro pumps, and a reaction vial, a product vial, a temporary storage vial, a filter membrane, and a waste vial, wherein the plurality of reagent vials include first reagent vial and second reagent vials being connected to the reaction vial through first micro pump, the third reagent vial and fourth reagent vial being connected to the reaction vial through second micro pump, fifth reagent vial being connected to the reaction vial through third micro pump, and sixth reagent vial being connected to the temporary storage vial through fourth micro pump, wherein the reaction vial is connected to the plurality of gel filtration columns through the micro-pump, respectively. The automated synthesis device is operable with program to upgrade yield and avoid contamination.

Abstract: A kit for preparing a radiolabeled liposome is provided, the kit including a liposome suspension and a radionuclide, wherein the liposome suspension includes a conjugate with a structure of [chelator-hydrophilic polymer-lipid]. A method for preparing a radiolabeled liposome using the kit is also disclosed herein, thereby the radiolabeled liposome being produced with the conjugate connected to the surface therein. The advantages of the present disclose such as simple, convenient and without purifying for the produced radiolabeled liposome are thus achieved. Further, the produced radiolabeled liposome has a high specific activity and a high sensitivity and suits for the clinical use.

Abstract: One pot process of preparing multifunctional liposome drug is provided. In this one pot process, liposome reacted with radionuclide labeled solution, chemotherapy drug, and targeted ligand at appropriate temperature. The product in this invention for preparation multifunctional liposome drugs in for imaging, delivery and targeting in cancer diagnosis and therapy has proved to be more simple, convenient, effective and easier than the prior art is.

Abstract: This invention is to manufacture a kit for preparation of nano-targeted liposome drugs in combined chemotherapy and radionuclide therapy. It is a kit consisting of three components: (1) A 10 ml vial A which contains BMEDA, gluconate acetate, SnCl2. (2) A 10 ml vial B which contains DSPC, cholesterol, DSPE-PEG, and Doxorubicin(DXR) (or Daunorubicin, Vinolbine). (3) A 10 ml vial C which contains 188ReO4? (or 186ReO4?) solution. The procedure of using the kit is as follows: (1) Remove the contents of the 188ReO4? (or 186ReO4?) solution from vial C. (2) Inject the 188ReO4? (or 186ReO4?) solution into the vial A, and the mixtures react in appropriate temperature. (3) Remove the contents of the 188Re-BMEDA (or 186Re-BMEDA) solution from vial A. (4) Inject the 188Re-BMEDA (or 186Re-BMEDA) solution into the vial B, and the mixtures react in appropriate temperature. The reconstituted solution in the vial B is applied to combine bimodality radiochemotherapy for treatment of tumor and ascites.

Abstract: The present invention discloses a method for preparing lipid-spacer-reactive functional group-peptide, wherein the peptide consists of 3 to 16 amino acid residues in which at least one amino acid residue is lysine (Lys), the reactive functional group is a formula of —X—CO—Y—CO—, wherein X represents an oxygen atom or a nitrogen atom, and Y represents C1-6 alkylene which may be interrupted by one or two oxygen or nitrogen atom(s), the spacer is a hydrophilic polymer, and the lipid is phosphatidylethanoaminecarbonyl represented by the formula (I): R1 and R2 are the same or different and individually represent linear or branch C7-30 alkyl or linear or branch C7-30 alkenyl; which is characterized in that the reaction is carried out in a liquid phase and comprises the following steps of (a) firstly protecting Lys amino acid residue in the peptide through a protection group; (b) subsequently reacting the peptide with the lipid-spacer-reactive functional group; and (c) finally removing the protection group from

Abstract: The present invention discloses a method for preparing lipid-spacer-reactive functional group-peptide, wherein the peptide consists of 3 to 16 amino acid residues in which at least one amino acid residue is lysine (Lys), the reactive functional group is a formula of —X—CO—Y—CO—, wherein X represents an oxygen atom or a nitrogen atom, and Y represents C1-6 alkylene which may be interrupted by one or two oxygen or nitrogen atom(s), the spacer is a hydrophilic polymer, and the lipid is phosphatidylethanoaminecarbonyl represented by the formula (I): R1 and R2 are the same or different and individually represent linear or branch C7-30 alkyl or linear or branch C7-30 alkenyl; which is characterized in that the reaction is carried out in a liquid phase and comprises the following steps of (a) firstly protecting Lys amino acid residue in the peptide through a protection group; (b) subsequently reacting the peptide with the lipid-spacer-reactive functional group; and (c) finally removing the protection group