نقشِ پائے شہِ ابرارؐ ؛ قمر کی رونق
کہکشائوں میں ڈھلی ، راہ گزر کی رونق
یہی دیواروں کی زینت ، یہی در کی رونق
ذکرِ سرکارِؐ دو عالم سے ہے گھر کی رونق
نقشِ نعلین نبیؐ سے ہے مدینے کی چمک
اسی دستار سے ہے میرے بھی سر کی رونق
رحمتِ کون و مکاںؐ جانِ دو عالم ٹھہری
یادِ محبوبِ خداؐ دل کے نگر کی رونق
آپؐ کے دم سے ہے اے صاحبِ لولاک لماؐ!
بحر و بر ، حجر و شجر ، شام و سحر کی رونق
لفظِ کُن ، روزِ ازل ، لوح و قلم ، عرشِ عُلی
آپؐ مخلوقِ خدا ، جنّ و بشر کی رونق
عدسئہ آنکھ میں ہے نورِ مُنوّر اُنؐ کا
نورِ محبوبِ خداؐ ، حسنِ نظر کی رونق
روزنِ چشمِ عقیدت سے حقیقت دیکھو
ذاتِ محبوبؐ سے اللہ کے گھر کی رونق
رونقِ چہرئہ اُمّت ہے شفاعت کے سبب
ہے ندامت سے بھری دیدئہ تر کی رونق
کاش عرفانؔ کی پلکوں کو بھی ہو جائے عطا
اُنؐ کی راہوں کو ملی لعل و گہر کی رونق
For the development of the interior Nation tolerance, peace, prosperity, ethical and spiritual development is very necessary. Islam is the religion of peace and safety. There is no scope for oppression and aggression in Islam. In Islam sustainable development is a process in which real income and per capita income of country increase as well as self-esteem, freedom of action and religious activity also increase. People should make best use of country’s means of production to create better conditions than the past. A great harden in society’s development is religious prejudice. Religious tolerance means to treat the follower of other religious without hurting their feeling and without any mistreatment just because of their views. We should not hate other religious and their follower although we do not agree with their philosophies and views. We should accept and fulfil their rights as human beings which God has bestowed with high status. We can understand breadth and depth of tolerance by the saying of Holy Prophet. In twenty-one century Europe ideas of tolerances have different meaning than Islam. This paper provides a literature review on this subject in the light of Holy Quran and Seerah of Holy Prophet.
The present investigation explored the potential of various physical, chemical, thermal, non-thermal and biological interventions, individually and in different combinations, to reduce bacterial populations on meat surfaces, thereby improving the quality and shelf stability of raw beef during refrigerate storage. Clove essential oil, hot water washing, UV light treatment and bacteriophage therapy were employed individually on meat fillets (beef) to evaluate their potential to improve safety and quality of meat. Subsequently, different combinations of these antimicrobial interventions were used as multiple hurdle technology to inactivate surface microflora of beef. Prior to any applications, clove powder was nutritionally characterized, and following optimization of an extraction protocol, antioxidant potential and antimicrobial efficacy of clove extracts was measured. For the extraction of polyphenols, four extraction methods were used: ethanol extraction (EE); n-hexane extraction (HE); petroleum ether extraction (PE); and steam distillation extraction (SE). Among these extraction methods, clove oil obtained through HE demonstrated highest extraction yield (48.84±0.13%), total phenolic contents (54.05±0.93 mg GAE/g), total flavonoid contents (15.54±0.46 mg quercetin/g), FRAP value (0.69±0.03 mg/mL) and DPPH activity (0.29±0.01 mg/mL). Additionally, HE clove extract showed the highest antimicrobial activity against all experimental pathogens, producing zones of inhibition of 24.27±0.32 mm for S. Typhimurium, 25.8±0.20 mm for E. coli and 29.67±0.35 mm for L. monocytogenes. With highest susceptibility shown by L. monocytogenes. Moreover, response surface methodology was applied to optimize the treatment combinations for all antimicrobial interventions before their final application on meat. For clove oil treatment, meat samples were dipped in solutions of three concentrations (0.5%, 1.0%, 1.5%) for three different time periods (1 min, 2 min, 3 min) and lowest total plate count (3.27 log CFU/g) and Listeria monocytogenes concentrations (2.29 log CFU/g) were recorded in samples immersed in 1.5% clove solution for 3 min. Additionally, immersion in clove solutions was helpful in improving meat qualityand oxidative stability during storage of 15 days. For hot water treatment, total plate count and L. monocytogenes concentrations were lowest on meat samples washed with hot water at 90°C for 90 s i.e., 2.62 log CFU/g and 2.27 log CFU/g respectively. However, drip loss and purge loss percentages were slightly higher and slight discoloration was seen with increase in heat. However, pH, TVBN, and texture values remained in acceptable ranges for all the hot water-treated samples. UV application also reduced total bacteria concentrations with lowest concentrations of total plate counts (2.86 log CFU/g) and L. monocytogenes numbers (2.71 log CFU/g) recovered on meat samples treated with UV light at 8 cm distance for 180 s. Likewise, treat with bacteriophages reduced growth of L. monocytogenes during storage from 5.2 log CFU/g on Day 1 to 3.9 log CFU/g on Day 5, 3.5 log CFU/g on Day 10 and 2.9 log CFU/g on Day 15. Among multiple hurdles, obtained log values of total plate count and L. monocytogenes numbers were 4.35 and 3.92 log CFU/g for dipping in clove oil solution (0.5%) at 60°C for 1 min., 3.31 and 3.26 log CFU/g for hot water wash (60°C) + UV treatment, 3.43 and 3.25 log CFU/g for clove solution dipping (0.5%) + UV treatment and 2.52 & 2.30 log CFU/g for hot water wash (60°C) + clove solution dipping (0.5%) + UV treatment. For phage combinations, L. monocytogenes concentrations were 2.91 log CFU/g for Phage + 0.5% clove essential oil, 2.39 log CFU/g for phage + UV treatment and 1.8 log CFU/g for phage + clove extract + UV treatment. Taken together, these data indicate that individual mitigation treatments each reduced bacterial concentrations on meat surfaces, but multi-hurdle approaches that employed the different treatments on sequence were most effective.Importantly, most mitigation treatments reduced bacterial concentrations without a concomitant decreased on meat quality as measured here.