عزل و تصنيف الطحلب الاخضر Stigeoclonium attenuatum و دراسة قدرته على تحضير اوكسيد الزنك النانوي zinc oxide nanoflakes و التكسير الضوئي لصبغة الميثيلين الازرق بواسطة ضوء
DOI:
https://doi.org/10.21123/bsj.2023.7231الكلمات المفتاحية:
فعالية المضاد الحيوي، المركبات البيوكيماوية الفعالة، الدقائق النانوية ، التحفيز الضوئي ، Stigeoclonium attenuatumالملخص
ساهمت الطحالب في العديد من المجالات الحيوية كمجال الصناعات الدوائية و المعالجة البيئية و كذلك في مجال التقنيات الحيوية . كما يعد مجال تخليق المركبات النانوية مجال واعد وفي تطور سريع لتقديم مختلف الحلول لاهم المشاكل الحالية التي تواجه المجتمع الطبي و المشاكل البيئية. تضمنت الدراسة الحالية عزل و تصنيف الطحلب الاخضر Stigeoclonium attenuatum (Hazen) F.S. Collins 1909من نهر الحلة ( محافظة بابل) في وسط العراق. تم التخليق الحيوي لاوكسيد الزنك ZnO nanoflakes بواسطة المستخلص المائي للطحلب . تم تشخيص الجزيئات النانوية بواسطة X-Ray diffraction (XRD) و المجهر الالكتروني الماسح (SEM) بمختلفة الاحجام بمدى يتراوح بين23-20 نانوميتر. كما تضمنت تجارب الدراسة اختبار قدرة مسحوق اوكسيد الزنك النانوي كمحفز ضوئي لهذا اجريت مجموعة من التجارب على تحليل صبغة ازرق الميثيلين ضوئيا Photocatalyst و ذلك بتعريضها لأشعة الشمس ، و بطول موجي 660 نانومينر اظهر الصبغة تلاشي تدريجي الى ان وصلت الى نقطة الاختفاء التام عند حوالي 60-120 دقيقة ، و بهذا فقد اظهر مسحوق اوكسيد الزنك النانوي فعالية تحليلية ضوئية عالية في تحليل الصبغة بكفاءة 97% . كما تم اختبار اوكسيد الزنك النانوي nanoflakes ZnO المحضر كضماد حيوي تجاه بعض السلالات البكتيرية المقاومة وهي كل من coli Escherichia و Klebsiella pneumoniae و aureus Staphylococcus و Streptococcus Sp.، وقد وجدت الدراسة ان فعالية المركب النانوي قد ازدادت بزيادة التراكيز وهي 50 و 100 و 150مايكروغرام/مليليتر.
Received 25/3/2022
Accepted 20/7/2022
Published Online First 20/1/2023
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