A method for manufacturing an electrical circuit component includes preparing a mixture of a structured material and silkworm food. The method further includes feeding the mixture to at least one silkworm. The method further includes harvesting silk produced by the at least one silkworm, wherein the harvested silk includes at least one silkworm silk fiber including silkworm-digested portions of the structured material embedded in or on the at least one fiber. The method further includes incorporating the at least one fiber into an electrical circuit component.

A method for manufacturing an electrical circuit component includes preparing a mixture of a structured material and silkworm food. The method further includes feeding the mixture to at least one silkworm. The method further includes harvesting silk produced by the at least one silkworm, wherein the harvested silk includes at least one silkworm silk fiber including silkworm-digested portions of the structured material embedded in or on the at least one fiber. The method further includes incorporating the at least one fiber into an electrical circuit component.

Disclosed is a method of efficiently producing a long bagworm silk thread containing no contaminant while preventing a change in the spinning direction and the runaway of the bagworm from a rail, and alleviating a burden on the bagworm; and an apparatus for implementing the thread-producing method. Provided is an apparatus for producing a bagworm silk thread, having a movable rail having a width smaller than the maximum width between the right and left legs of a bagworm and configured to move in the longitudinal direction and to be able to hold with the legs of the bagworm; and a fixator configured to fix a bagworm, wherein the fixator is placed at a position such that the fixed bagworm can hold the movable rail.

Disclosed is a method of efficiently producing a long bagworm silk thread containing no contaminant while preventing a change in the spinning direction and the runaway of the bagworm from a rail, and alleviating a burden on the bagworm; and an apparatus for implementing the thread-producing method. Provided is an apparatus for producing a bagworm silk thread, having a movable rail having a width smaller than the maximum width between the right and left legs of a bagworm and configured to move in the longitudinal direction and to be able to hold with the legs of the bagworm; and a fixator configured to fix a bagworm, wherein the fixator is placed at a position such that the fixed bagworm can hold the movable rail.

The present inventors have conducted intensive studies on an antibody which controls HIV in an administration group with a high probability over a long period of time with one or several times of single-agent administration. As a result, the present inventors have surprisingly found that, when an SW-1C10 antibody, which is obtained by producing an antibody gene reported as 1C10 in silkworms, is singly administered only a few times, the viral load in the blood is suppressed to the detection limit or lower at an early stage in all of individuals to which the antibody has been administered, and moreover, the viral RNA load in the blood is maintained at the detection limit or lower for a long time of 12 weeks.

The present inventors have conducted intensive studies on an antibody which controls HIV in an administration group with a high probability over a long period of time with one or several times of single-agent administration. As a result, the present inventors have surprisingly found that, when an SW-1C10 antibody, which is obtained by producing an antibody gene reported as 1C10 in silkworms, is singly administered only a few times, the viral load in the blood is suppressed to the detection limit or lower at an early stage in all of individuals to which the antibody has been administered, and moreover, the viral RNA load in the blood is maintained at the detection limit or lower for a long time of 12 weeks.

A method for evaluating biofilm formation on a medical device material in vivo using an invertebrate includes: a step of inserting the medical device material between a hypodermal portion and an intestinal tract of an invertebrate, a step of extracting the medical device material from the invertebrate, and a step of evaluating biofilm formation on the surface of the medical device material; the invertebrate is for use in this evaluation of the biofilm formation.

A method for evaluating biofilm formation on a medical device material in vivo using an invertebrate includes: a step of inserting the medical device material between a hypodermal portion and an intestinal tract of an invertebrate, a step of extracting the medical device material from the invertebrate, and a step of evaluating biofilm formation on the surface of the medical device material; the invertebrate is for use in this evaluation of the biofilm formation.