نقش مهندسی شیمی در توسعه مهندسی (زیست) ‌پزشکی‎

واشقانی فراهانی, ابراهیم; رفیعیان, سعید

doi:10.22047/ijee.2024.447692.2064

نقش مهندسی شیمی در توسعه مهندسی (زیست) ‌پزشکی‎

نوع مقاله : مقاله علمی -پژوهشی ( ویژه نامه شیمی )

نویسندگان

ابراهیم واشقانی فراهانی

سعید رفیعیان

دانشگاه تربیت مدرس

https://doi.org/10.22047/ijee.2024.447692.2064

چکیده

در این مقاله کوتاه، نخست به نقش مهندسی شیمی در کاربردهای سلامت انسان، با تمرکز ویژه بر مهندسی (زیست)‌پزشکی اشاره می‌شود. سپس سابقه تاریخی این نقش در آغاز فعالیت مهندسان شیمی در این زمینه با تأکید بر موارد مهم، بررسی خواهد شد. در ادامه افق‌های پیش روی مهندسی شیمی در چند زمینه مهم کاربرد مهندسی شیمی در پزشکی مانند زیست‌مواد، سامانه‌های دارورسانی و مهندسی بافت، به صورت فشرده توضیح داده می‌شوند. سپس چگونگی کاربرد اصول مهندسی شیمی، در پیوند مهندسی شیمی و مهندسی بافت‌پزشکی بالینی به صورت فشرده بیان می‌شود. آنگاه به چگونگی پدیدار شدن درس‌های مربوط به گرایش مهندسی (زیست)‌پزشکی در برنامه آموزشی مهندسی شیمی و توسعه آن تا امروز، از جمله برنامه آموزشی کارشناسی ارشد مهندسی شیمی- زیست‌پزشکی در ایران پرداخته و در پایان نتیجه‌گیری کوتاه ارائه خواهد شد.

کلیدواژه‌ها

مهندسی شیمی

مهندسی زیست‌پزشکی

زیست‌مواد

دارورسانی

بافت

برنامه درسی

20.1001.1.16072316.1403.26.103.6.5

موضوعات

تحقیق و پژوهش

عنوان مقاله English

CHEMICAL ENGINEERING ROLE IN DEVELOPING BIOMEDICAL ENGINEERING

نویسندگان English

Ebrahim Vasheghani-Farahani

Saeed Rafieyan

Tarbiat Modares University

چکیده English

In this article, the role of chemical engineering in human health applications is mentioned first, with a particular focus on (bio)medical engineering. Then, the historical background of this role at the beginning of chemical engineers’ activities in this field will be examined with emphasis on important issues. In the following, the future horizons of chemical engineering in several important fields of application in medicine, such as biomaterials, drug delivery systems, and tissue engineering, are explained briefly. Then, the importance of applying chemical engineering principles in the link between chemical engineering and tissue engineering/clinical medicine (translational medicine) is intensively expressed. Finally, how the lessons related to (bio)medical engineering emerged in the chemical engineering educational program and its development until today, including the master’s program of chemical-biomedical engineering in Iran, and a short conclusion will be presented at the end.

کلیدواژه‌ها English

Chemical engineering

biomedical

biomaterials

drug delivery

tissue engineering

curriculum

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