Organizing Active Learning Models in Science Classes (2)

The purpose of this study is to organize active learning models in science classes. Through classroom practice from elementary school to upper secondary school, we observed the followings: 1) the "reciprocal of internalization and externalization," which means collaborative and cooperative learning, is the key to active learning in science lessons; 2) by creating a "subject skeleton," teachers can gain clarity regarding the promotion of deep learning and organize active learning models in science classes

Organizing of Active Learning Models in Science Classes (2)

The purpose of this study is to organize active learning models in science classes. Through classroom practice from elementary school to upper secondary school, we observed the following: 1) the "reciprocal of internalization and externalization," which means collaborative and cooperative learning, is the key to active learning in science lessons; 2) by creating a "subject skeleton," teachers can gain clarity regarding the promotion of deep learning and organize active learning models in science classes

Active Learning Models in Science Classes

研究の第１年次に当たる本年は，理科におけるアクティブラーニング型授業の構造化に向けて，内化と外化の往還を取り入れた授業デザインとその実践に取り組み，具体的実践の蓄積を行った。小学校，中学校，高等学校それぞれで実践を行ったところ，１）学習内容の定着が図られる，２）発展的な内容や未習内容を生徒が主体的に理解することが可能である，３）協働的な学びの場面を加えることで理解の深化が図られる，４）どのような課題に取り組ませるのかといった課題の設定がカギである，５）アクティブラーニングであるか否かを判断するための要素を明らかにする必要がある，などの一定の成果と課題が明らかになった。The purpose of this study is to create active learning models in science classes. As the first-year research, the authors designed the classes which would include a round trip between externalization and internalization, and put them into practice. The designed models were adopted in elementary, junior high and senior high school classes. What have become clear are as the following; 1) Students’ acquisition of the learning contents can be promoted, 2) Students can understand advanced contents proactively, 3) Students’ learning can be deepened by adding collaborative activities, 4) The success or failure to active learning may depend on the quality of the tasks which students work on, 5) It is necessary to clarify the factors to determine active learning

The Role of Science Education in the Construction of a Knowledge-Based Society

知識基盤社会における理科の役割は，科学的に探究する活動を通して得られた結果（情報）を活用し，それらの情報から導き出した自らの考えを表現する能力を高めることである。これまでに明らかになったことは，授業者が実験結果に対して関連付けることができる事項を明確にし，分析・解釈する視点を与えることが重要であるということである。今年度は，小学校，中学校，高等学校の理科で，パフォーマンス課題を取り入れた探究活動を行い，多くの授業者が共有できる方向性を考えた。実践の結果，以下のことが明らかになった。１）小集団での話し合いの質を高めるためには，話し合いの目的と方法を明示することが重要であること。２）そのために授業者の関わり方を引き続き検討する必要があること。３）パフォーマンス課題の設計には授業者がよりメタ認知を働かせることが必要であること。今後は，このような実践経験を広く共有すべきであると考えている。Science education should help students to utilize results and information through activities, to investigate scientifically, and to develop their abilities to express ideas they have derived from those results. We have learned that it is important for instructors to clarify which results from experiments relate to each other and to give students some clear perspectives for analyzing and interpreting them. This academic year, we investigated performance tasks at elementary, junior high, and senior high school levels. Through our research we have learned that to improve the quality of discussion in small groups, it is important to make the purpose and method clear. We also showed that instructors should monitor how they engage with students in the course of discussion and that they need to function meta-cognitive abilities more to design performance tasks

Safety and pharmacokinetics of recombinant human hepatocyte growth factor (rh-HGF) in patients with fulminant hepatitis: a phase I/II clinical trial, following preclinical studies to ensure safety

<p>Abstract</p> <p>Background</p> <p>Hepatocyte growth factor (HGF) stimulates hepatocyte proliferation, and also acts as an anti-apoptotic factor. Therefore, HGF is a potential therapeutic agent for treatment of fatal liver diseases. We performed a translational medicine protocol with recombinant human HGF (rh-HGF), including a phase I/II study of patients with fulminant hepatitis (FH) or late-onset hepatic failure (LOHF), in order to examine the safety, pharmacokinetics, and clinical efficacy of this molecule.</p> <p>Methods</p> <p>Potential adverse effects identified through preclinical safety tests with rh-HGF include a decrease in blood pressure (BP) and an increase in urinary excretion of albumin. Therefore, we further investigated the effect of rh-HGF on circulatory status and renal toxicity in preclinical animal studies. In a clinical trial, 20 patients with FH or LOHF were evaluated for participation in this clinical trial, and four patients were enrolled. Subjects received rh-HGF (0.6 mg/m²/day) intravenously for 12 to 14 days.</p> <p>Results</p> <p>We established an infusion method to avoid rapid BP reduction in miniature swine, and confirmed reversibility of renal toxicity in rats. Although administration of rh-HGF moderately decreased BP in the participating subjects, this BP reduction did not require cessation of rh-HGF or any vasopressor therapy; BP returned to resting levels after the completion of rh-HGF infusion. Repeated doses of rh-HGF did not induce renal toxicity, and severe adverse events were not observed. Two patients survived, however, there was no evidence that rh-HGF was effective for the treatment of FH or LOHF.</p> <p>Conclusions</p> <p>Intravenous rh-HGF at a dose of 0.6 mg/m²was well tolerated in patients with FH or LOHF; therefore, it is desirable to conduct further investigations to determine the efficacy of rh-HGF at an increased dose.</p

A Research on a New Science Curriculum Development Based on ‘Nature Of Science’ Ⅲ : Reconstruction of a Coherence Science Curriculum from Elementary School to Upper Secondary School

本研究は，新しい科学観を取り入れた小学校から高等学校までの理科カリキュラムを開発することを目的としており，今年度は３年次にあたる。これまでの成果と課題をもとに，初等・中等教育で一貫して「科学の本質」を学ぶためのフレームワーク構築に向け，小学校から高等学校を通じて系統的に取り扱うことが可能な内容について検討を行った。 中学校における実践からは，理科教師が，科学者コミュニティーによる知，政策決定者や教師たちによる教えるべき知，児童・生徒の発達段階や文脈などを考慮した教える知，について可能な限り熟知する必要があることが示唆された。また，論証活動を行う際の，教師の振る舞い方も重要であることも明らかとなった。 また，小学校における実践では，学年による差異はあるものの，見たことや考えたことの違いを次第に意識化させることによって，観察や実験等のレポートの書き方の指導にも繋がることが明らかとなった。 以上の実践より，科学の本質を初等・中等教育で一貫して教えるためには，これまでの実践の視点の変容に基づく教師による授業方略の在り方や投げ込み的教材を使用する教師の意図が，いかに重要であるかを示唆している。This study develops a new science curriculum for elementary to upper secondary schools which include the concept of the “Nature of Science”. We examined possible content to build a systematic framework for mentioned above science education. The practice at junior high school shows that teachers should be familiar with scholarly knowledge, knowledge to be taught by the policy makers and teachers, and taught knowledge which students understand through learning along with the students’ ages and contexts. The teacher’s behavior in argumentation by pupils is also important. The practice at elementary school shows that perceptions of the crucial distinction between inference and observation lead students to write good reports. These practices exemplify that teaching Nature of Science consistently to elementary and lower secondary students should largely depend on the teachers’ methods of instruction and what material they develop from a new viewpoint