Womb : A Human Production Machine

 A machine is a device or tool that uses energy to perform a specific task or function, typically involving mechanical, electrical, or computational operations. Machines often transform energy or resources into work or a desired outcome.

Machines generally consist of various parts that work together. 

We are nothing but some code. We are codes. DNA is made with code. DNA is made with molecules. molecules has Nucleus and Proton, Electron. These are charge. either positive or negative. 

1. Charge Interaction:

   • You're suggesting that during fertilization, the interaction between the positively charged environment and the negatively charged chromosomes from the sperm and egg influences which sperm successfully fertilizes the egg.

2. Variability of Charges:

   • You propose that the charges of the nucleotides in the chromosomes can vary, creating a dynamic interaction where more negatively charged nucleotides are drawn to those with comparatively less negative charge.

Specific Sperm and Egg Charges:

• Sperm 1:

  • Dad’s Y chromosome: 1 (+)
  • Dad’s X chromosome: 1 (-)

• Sperm 2:

  • Dad’s Y chromosome: 2 (+)
  • Dad’s X chromosome: 2 (-)

• Sperm 3:

  • Dad’s Y chromosome: 3 (+)
  • Dad’s X chromosome: 3 (-)

• Egg:

  • Mom’s chromosomes: Z (3C)

Selection of Sperm:

• You suggest that Sperm 3, with a balanced charge (3C) on both X and Y chromosomes, will successfully fertilize the egg, which has a charge of 3C. This implies a favorable interaction based on charge compatibility.

DNA : Made with tiny nucleotide. Some nucleotides are as below : 

Deoxyadenosine Monophosphate (dAMP)

• Chemical Formula: C₁₀H₁₃N₅O₇P

Deoxythymidine Monophosphate (dTMP)

• Chemical Formula: C₁₀H₁₄N₂O₈P 

Deoxyguanosine Monophosphate (dGMP)

• Chemical Formula: C₁₀H₁₃N₅O₈P

the molecules involved in DNA, particularly the nucleotides, can indeed carry charges under certain conditions. it is possible for some molecules involved in DNA to be positively charged while others are negatively charged.

1. Phosphate Group:

• The phosphate group (PO₄³⁻) is negatively charged. This negative charge plays a critical role in the structure and function of DNA.
• In an aqueous environment, the phosphate group can lose protons (H⁺ ions), leading to a more stable negative charge. This negative charge helps in the formation of the sugar-phosphate backbone, allowing the nucleotides to link together through phosphodiester bonds.

2. Nucleotides:

• The overall charge of a nucleotide depends on the state of the phosphate group. Since it is negatively charged, each nucleotide contributes a negative charge to the DNA molecule.
• When DNA is in solution (like in the cell), the phosphate groups are usually fully ionized, giving the DNA strand a net negative charge.

3. Nitrogenous Bases:

• The nitrogenous bases (adenine, thymine, guanine, and cytosine) are generally neutral at physiological pH (the pH level in the body, around 7.4). However, they can participate in protonation and deprotonation depending on the local environment (like pH changes).
• For example, cytosine can gain a proton under acidic conditions, which may lead to it being positively charged.

4. Implications of Charges:

• The negative charge on the DNA molecule affects its interactions with proteins, enzymes, and other molecules in the cell. It plays a significant role in:
• DNA stability: The negative charge repels other DNA strands, helping maintain the double helix structure.
• Binding with proteins: Many proteins that interact with DNA (like transcription factors) have positively charged regions that can bind to the negatively charged DNA.

5. 

Positively Charged Molecules:

• Nitrogenous Bases: While the nitrogenous bases (adenine, thymine, guanine, and cytosine) are generally neutral at physiological pH, they can become positively charged under certain conditions:
• For example, cytosine can gain a proton (H⁺) under acidic conditions, making it positively charged. Similarly, guanine can also accept a proton under specific conditions.

so can we say these : 

molecules = codes:

nucleotide = small blocks of codes,

dna = a group of small blocks of codes that can perform an action,

mitochondria = a box of a group that can do 1 complete task. (example : process atp)

a cell = a fully functional, multi tasking THING.

cell division = automatic copying of blocks and blocks of codes and automatic variation

millions cell division = trillions trillions codes.

* like we can program semi-conductors in a way to store data, as dna is nothing but a combination of codes, so we can store data at dna as well.

* we r made with star dust, star dust is made with SOME kind of molecules that is ONE kind of code, we have codes in us from star dust, star dust belongs to bigbang theory. so before bigbang, there was nothing. nothing means nothing, no code. so SOMETHING made a code. An automatic copy Code. It doubled into 2. then 4, 8 etc etc into millions, big bang is the moment when a successfull copy is done. thats how before bigbang, there was nothing. that how we are created from nothing. thats how multi-verse existence came true. 

Big Bang

   └── Formation of Fundamental Particles

       ├── Quarks and Electrons

       ├── Protons and Neutrons

       └── Formation of Atoms (Hydrogen, Helium)

           └── Formation of Stars

               ├── Nuclear Fusion in Stars

               │   └── Creation of Heavier Elements (C, O, Fe)

               └── Supernova Explosions

                   └── Distribution of Stardust

                       ├── Formation of New Stars and Planets

                       └── Formation of Solar Systems (including Earth)

                           └── Creation of Life

                               └── Us (Made of Stardust)