Always like this bro
Always like this bro
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Looking for a hearty, one-pan dish that’s both delicious and easy to whip up? Try this Ground Beef and Chopped Cabbage skillet! It's a comforting meal that's perfect for busy weeknights.
Ingredients:
- 1 small cabbage, chopped
- 1 lb ground beef
- 1 can diced tomatoes (15 oz)
- 1 cup onions, chopped
- 2 garlic cloves, minced
- 1 tablespoon bouillon powder
Directions:
1. In a large skillet over medium heat, brown the ground beef until it’s fully cooked, breaking it apart as it cooks.
2. Toss in the chopped onions and minced garlic, sautéing them together until the onions turn translucent and fragrant.
3. Add the chopped cabbage and diced tomatoes to the skillet, mixing all the ingredients for a hearty combination.
4. Sprinkle in the bouillon powder and season with salt and pepper to taste. Stir everything together.
5. Cover the skillet and let it cook for about 10-15 minutes, stirring occasionally until the cabbage is tender and lovely.
6. Serve hot and enjoy this delicious dish!
Nutritional Values (per serving):
- Serving Size: 1 cup
- Calories: 320
- Protein: 20g
- Carbohydrates: 15g
- Fat: 20g
- Fiber: 4g
#ComfortFood #OnePanMeal #HealthyEating #EasyRecipes #DinnerIdeasLooking for a hearty, one-pan dish that’s both delicious and easy to whip up? Try this Ground Beef and Chopped Cabbage skillet! It's a comforting meal that's perfect for busy weeknights. Ingredients: - 1 small cabbage, chopped - 1 lb ground beef - 1 can diced tomatoes (15 oz) - 1 cup onions, chopped - 2 garlic cloves, minced - 1 tablespoon bouillon powder Directions: 1. In a large skillet over medium heat, brown the ground beef until it’s fully cooked, breaking it apart as it cooks. 2. Toss in the chopped onions and minced garlic, sautéing them together until the onions turn translucent and fragrant. 3. Add the chopped cabbage and diced tomatoes to the skillet, mixing all the ingredients for a hearty combination. 4. Sprinkle in the bouillon powder and season with salt and pepper to taste. Stir everything together. 5. Cover the skillet and let it cook for about 10-15 minutes, stirring occasionally until the cabbage is tender and lovely. 6. Serve hot and enjoy this delicious dish! Nutritional Values (per serving): - Serving Size: 1 cup - Calories: 320 - Protein: 20g - Carbohydrates: 15g - Fat: 20g - Fiber: 4g #ComfortFood #OnePanMeal #HealthyEating #EasyRecipes #DinnerIdeas
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TITAN SEAFOOD MEDLEY DEEP DISH
Ingredients:
1 deep-dish crust
½ lb shrimp, peeled & cooked
½ lb calamari rings, cooked
½ lb lobster or crab meat
2 cloves garlic, minced
½ cup diced shallots
½ cup heavy cream
1 ½ cups shredded mozzarella or Gruyère
Splash of lemon juice
Fresh parsley or dill
Salt, pepper & chili flakes (optional)
Instructions:
1⃣ Sauté garlic & shallots in butter till soft.
2⃣ Add cream, lemon, and seasonings—simmer gently.
3⃣ Fold in seafood and half the cheese.
4⃣ Fill crust with creamy seafood mix, top with remaining cheese.
5⃣ Bake at 375°F (190°C) for 25–30 min until golden & bubbly.
6⃣ Garnish with herbs, serve deep, rich, and ocean-loaded!
Prep: 20 min | Cook: 30 min | Total: 50 min | Serves: 4TITAN SEAFOOD MEDLEY DEEP DISH Ingredients: 1 deep-dish crust ½ lb shrimp, peeled & cooked ½ lb calamari rings, cooked ½ lb lobster or crab meat 2 cloves garlic, minced ½ cup diced shallots ½ cup heavy cream 1 ½ cups shredded mozzarella or Gruyère Splash of lemon juice Fresh parsley or dill Salt, pepper & chili flakes (optional) Instructions: 1⃣ Sauté garlic & shallots in butter till soft. 2⃣ Add cream, lemon, and seasonings—simmer gently. 3⃣ Fold in seafood and half the cheese. 4⃣ Fill crust with creamy seafood mix, top with remaining cheese. 5⃣ Bake at 375°F (190°C) for 25–30 min until golden & bubbly. 6⃣ Garnish with herbs, serve deep, rich, and ocean-loaded! Prep: 20 min | Cook: 30 min | Total: 50 min | Serves: 4
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Scientists from the University of Bayreuth in Germany have successfully created the world’s first gene-edited spider that produces glowing red silk threads.
Using CRISPR-Cas9 gene editing, they inserted a red fluorescent protein gene (mRFP) directly into the silk-producing genes of the common house spider (Parasteatoda tepidariorum).
As a result, some offspring were able to spin fluorescent red silk, visible under UV light—a strong sign that the gene modification worked precisely.
This breakthrough is the first time CRISPR has been used to achieve a gene "knock-in" in spiders, and it demonstrates that functional proteins can be genetically embedded into silk threads.
In the same study, researchers also knocked out a gene responsible for eye development, causing spiders to hatch without eyes—further proving the precision of their genetic editing method.
The research was published in the peer-reviewed journal Angewandte Chemie and has received international attention.
Funded by organizations including the U.S.
Navy and Air Force, the project could lead to supermaterials for use in defense, aerospace, textiles, and biomedicine—such as biodegradable sensors or stronger-than-steel fibers.
In summary, this marks a significant leap in bioengineering and spider silk research, unlocking future possibilities to design silk with custom traits directly within spiders themselves.Scientists from the University of Bayreuth in Germany have successfully created the world’s first gene-edited spider that produces glowing red silk threads. Using CRISPR-Cas9 gene editing, they inserted a red fluorescent protein gene (mRFP) directly into the silk-producing genes of the common house spider (Parasteatoda tepidariorum). As a result, some offspring were able to spin fluorescent red silk, visible under UV light—a strong sign that the gene modification worked precisely. This breakthrough is the first time CRISPR has been used to achieve a gene "knock-in" in spiders, and it demonstrates that functional proteins can be genetically embedded into silk threads. In the same study, researchers also knocked out a gene responsible for eye development, causing spiders to hatch without eyes—further proving the precision of their genetic editing method. The research was published in the peer-reviewed journal Angewandte Chemie and has received international attention. Funded by organizations including the U.S. Navy and Air Force, the project could lead to supermaterials for use in defense, aerospace, textiles, and biomedicine—such as biodegradable sensors or stronger-than-steel fibers. In summary, this marks a significant leap in bioengineering and spider silk research, unlocking future possibilities to design silk with custom traits directly within spiders themselves.
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A groundbreaking study suggests that our early Sun may have been encircled by massive rings of dust—structures that shaped the very layout of our Solar System and may have prevented Earth from becoming a super-Earth.
According to researchers, these dusty rings were created by pressure “bumps”—high-pressure zones caused as particles spiraled inward, heated up, and released gases through vaporization.
These zones formed sublimation lines, where materials like silicates, water ice, and carbon monoxide turned from solid to gas. As a result, dust got trapped instead of falling into the Sun, clumping into planetesimals—the seeds of planets.
Simulations showed that:
The inner ring gave rise to Mercury, Venus, Earth, and Mars
The middle ring helped birth the gas giants
The outer ring contributed to comets, asteroids, and Kuiper Belt objects
Interestingly, had the middle ring formed a bit later, more material could have gathered in the inner Solar System—potentially allowing super-Earths to form. Their absence is one of the mysteries that sets our planetary system apart from others across the galaxy.
RESEARCH PAPER
Andre Izidoro et al., Planetesimal rings as the cause of the Solar System’s planetary architecture, Nature Astronomy (2022)A groundbreaking study suggests that our early Sun may have been encircled by massive rings of dust—structures that shaped the very layout of our Solar System and may have prevented Earth from becoming a super-Earth. According to researchers, these dusty rings were created by pressure “bumps”—high-pressure zones caused as particles spiraled inward, heated up, and released gases through vaporization. These zones formed sublimation lines, where materials like silicates, water ice, and carbon monoxide turned from solid to gas. As a result, dust got trapped instead of falling into the Sun, clumping into planetesimals—the seeds of planets. Simulations showed that: The inner ring gave rise to Mercury, Venus, Earth, and Mars The middle ring helped birth the gas giants The outer ring contributed to comets, asteroids, and Kuiper Belt objects Interestingly, had the middle ring formed a bit later, more material could have gathered in the inner Solar System—potentially allowing super-Earths to form. Their absence is one of the mysteries that sets our planetary system apart from others across the galaxy. RESEARCH PAPER Andre Izidoro et al., Planetesimal rings as the cause of the Solar System’s planetary architecture, Nature Astronomy (2022)
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