Week 1 HW: Principles and Practices

šŸ§¬ 1. First, describe a biological engineering application or tool you want to develop and why.

Here are some ideas that I brainstormed:

šŸ©¹ Regenerative Medicine

  • Autologous skin graftsĀ to replace necrotic, cancerous, scarred, or miscoloured tissue etc
  • Synthetic skin modelsĀ for surgeons or tattoo artists to practice on
  • Self regenerating organsĀ (for people with damaged organs, cancer, people who need transplants i.e. bioink)
  • Cure for frostbiteĀ ā†’ regenerating cell tissue or even whole digits or limbs!
  • Growing teeth in a labĀ to replace damaged or missing teeth!
  • Regeneration of spinal column

šŸ§Ŗ Cures

  • Targeting misfolded proteins (prions)Ā in the brain
  • Making malarial mosquitos infertileĀ (* ethical considerations)
  • Synthesising biofuel
  • AIDS cure
  • Cancer detection mechanismĀ to cause cellular death/induce apoptosis in abnormal cells
  • Cure for sickle cell
  • Cure for cataractsĀ by growing autologous lenses
  • Cure for blindness or eyesight degeneration
  • Making VADsĀ ā†’ (HKU hydrogel transistors, electrical interaction with living cells)
  • Helping diabeticsĀ to endogenously produce effective insulin

šŸ›”ļø Prophylaxis

  • Predicting/modelling viruses and vaccinesĀ (* ethics/dangers must be taken into consideration)

šŸ­ Biomaterial/Industrial applications

  • Manufacturing leatherĀ without the need for mass animal slaughter
  • Bioplastic on industrial scaleĀ (mitigation of microplastic crisis)
  • Industrially producing natural inks
  • Bioremediation:
    • Landfills
    • Radioactive sites
    • Sewage systems

šŸŽ­ Fun ideas

  • Tabulating or transcribing music on plantsĀ (patterns on leaves ā†’ gene expression)
  • Bioluminescent lampsĀ for:
    • industrial applications
    • architectural applications (can be used practically in hospitals, clubs as exit signs etc)
    • design/decor!
    • bioluminescent paint
    • hair dye/cosmetics
  • Printing the taste of a meal!Ā for art/deisgn installation involving the coding of Hana programme/Hana AI to detect what is in an image and ā€œprint outā€ certain proteins? that correspond to flavours etc
    • edible
  • Print out QR codes on biomaterial to be scanned and play musicĀ for art/design installations
    • or if not QR codes then fun characters or shapes (presets) that can be scanned by Hana programme/Hana AI which then play certain songs?
    • stills from films even?
    • covers of albums?
  • Mushroom testing kitĀ which prints out species name on flesh of mushroom or testing strip once pricked or sample collected (kind of like pregnancy test but not, more like DNA sequencing mushrooms to determine what species that are)
  • Sustainable nail polish
  • Generating music from colony of bacteriaĀ for art/design/science installation

. . . In the end I decided that I would like to pursue further the idea of printing an image as well as the taste of a food/meal using edible media. I would like to call it ā€œTastemakerā€ or ā€œYum Dot Com.ā€ This project highlights the sensory potential of biological engineering, whilst sitting at the intersection of biology, technology, design, the culinary, and the quotidian human experience.

āš–ļø 2. Next, describe one or more governance/policy goals related to ensuring that this application or tool contributes to an ā€œethicalā€ future.

šŸ” Data Protection and Consent

  • This application will be handilng datasets in the form of photos that are submitted by users, therefore it is important that they know what their images are being used for, where they will be held, how they will be held, and who will have access to them ā†’ Images submitted by users constitute personal data under GDPR and related frameworks
  • Explicit consent must be given by participants to enable the use of their photographs/images
  • Participants may withdraw their consent at any moment

šŸ”Ž Promoting transparency

  • Ensure consumers understand what biological materials are being used, how the food is produced, and what they are ingesting
  • Clearly distinguish between artistic/experimental food products and nutritionally complete or medically relevant foods
  • Prevent deceptive use in advertising, novelty food products, or commercial settings

šŸ§Æ Preventing Malfeasance

  • Ensure that edible biological media used to print images and taste profiles is safe to consume, ethically produced, and not misleading or harmful, while still allowing creative and experimental uses:
  • Ensure all edible media and biological components are non-toxic, allergen-aware, and safe for repeated consumption
  • Prevent accidental or intentional contamination during production, printing, or distribution
  • Avoid misleading representations of nutritional value or ingredients (e.g. printing ā€œhealthyā€ foods that are not)
  • Avoid applications that could be used to manipulate consumers, i.e. by falsely replicating branded foods, culturally significant dishes, or nutritionally complete meals
  • Ensuring the technology is not repurposed for coercive or exploitative contexts, such as pressuring individuals to consume unfamiliar or unsafe substances i.e. spiking or biowarfare

šŸ§© Non-malificence

  • Prevent misuse of biosensing infrastructure for coercive surveillance or targeting specific communities
  • Make sure that biomaterial is sourced as ethically as possible
šŸ§­ 3. Next, describe at least three different potential governance ā€œactionsā€

šŸ“ Mandatory Explicit Consent & Transparency Requirements

Purpose:

- To ensure users submit images voluntarily to have most fun and intersting experience - To prevent misuse of images

Design:

- Actors include app developers, and users, potential patrons/donors/commisioners i.e. contemporary art galleries, museums - Mandatory consent form - Consent must be opt-in, and users can revoke it at any time with data deletion confirmed - Creation of a dashboard to manage or delete submissions

Assumptions:

- Users will read and understand consent forms. - App will faithfully implement deletion and management protocols - Regulatory bodies will enforce compliance

Risks of Failure & ā€œSuccess:ā€

- Failure: Users ignore consent warnings, app mishandles data, or withdrawal requests are delayed/inefficiently processed
  • Success: Overly strict consent enforcement may slow down research or creative experimentation

šŸ§° Technical data safeguards

Purpose:

- Reduce risk of data breaches

Design:

- Actors include App developers, IT/security teams. - Store images in encrypted servers - Remove metadata or personal identifiers when possible (data minimisation)

Assumptions:

- Sufficient encryption/safety measures in place - Users will take/upload appropriate photographs of food items - Users will read and understand how their data is handled and trust system to protect it

Risks of Failure & ā€œSuccess:ā€Ā  Failure: - Hacking or accidental leaks - Users abuse terms of upload

Success:

  • Minimal data retention may limit research/creativity

šŸ„½ Safety standards for edible media

Purpose:

- Prevent malfeasance/negligence in food production (contamination, allergens, deceptive use) while enabling creative applications

Design:

- Actors include: Food safety regulators (e.g., FDA, EFSA), companies producing edible media - Develop guidelines and certification for safe edible inks and substrates, including allergen disclosure - Require periodic audits/inspections

Assumptions:

- Regulatory frameworks can be adapted to new bioengineered food technologies

Risks of Failure & ā€œSuccess:ā€

- Failure: Lack of legislature or enforcement can lead to dangerous practices
  • Success: excessive regulation could slow innovation or increase costs

šŸ“Š 4. Scoring Policy Goals

Option 1: Mandatory consent & transparency
Option 2: Technical data safeguards
Option 3: Regulatory oversight for edible media

Does the option:Option 1Option 2Option 3
Enhance Biosecurity
ā€¢ By preventing incidentsN/A11
ā€¢ By helping respondN/A11
Foster Lab Safety
ā€¢ By preventing incidentN/A11
ā€¢ By helping respondN/A11
Protect the environment
ā€¢ By preventing incidents1N/A1
ā€¢ By helping respond1N/A1
Other considerations
ā€¢ Minimizing costs and burdens to stakeholders112
ā€¢ Feasibility?111
ā€¢ Not impede research223
ā€¢ Promote constructive applications111

āš ļø 5. Ethical concerns highlighted above

šŸ“š Homework Questions from Professor Jacobson

Natureā€™s machinery for copying DNA is called polymerase. What is the error rate of polymerase? How does this compare to the length of the human genome? How does biology deal with that discrepancy?

  • Naturual error rate: 1:10ā¶ or 1 in a million
  • Human error rate: 1:10Ā² or 1 in a hundred
  • Biological mechanisms are x10ā“ or 10,000 better than human ones The length of the human genome is roughly 3.2 billion base pairs.

Biology deals with this discrepancy through built in error correction mechanisms; 3ā€™-5ā€™ exonuclease activity which is an intrinsic ā€œproofreadingā€ function is an example of this. Exonucleases are specialist enzymes which catalyse the removal of incorrectly incorporated nucleotides by breaking phosphodiester bonds via hydrolysis.

Furthermore, the genetic code is particularly robust due to its degeneracy meaning that multiple codons can code for the same amino acid i.e. all of the codons for alanine start with GC, all of the codons for leucine start with CU etc. In this way, the effect of mutations can be mitigated. Moreover in the case of a conservative substitution (or replacement), which is a missense mutation (whereby a nucleotide change results in a different amino acid being incorporated into a protein), the incorrect amino acid has similar physicochemical properties to the original one and therefore does not affect the proteinā€™s tertiary or 3D structure. Physicochemical properties in this instance refer mostly to hydrophobicity and size.

How many different ways are there to code (DNA nucleotide code) for an average human protein? In practice what are some of the reasons that all of these different codes donā€™t work to code for the protein of interest?

Theoretically a lot. šŸ˜¹ This is due to the degenerate nature of the genetic code. Practically speaking, not all of these different codes work to code the protein of interest as Cells engaged in translation prefer certain codons Rare codons correspond to rare tRNA molecules The number of actually functional proteins is smaller than the theoretical possibilities

šŸ§Ŗ Homework Questions from Dr. LeProust

Whatā€™s the most commonly used method for oligo synthesis currently?

Currently, the most commonly used method for oligo synthesis is through phosphoramidite chemistry via the phosphodiester method pioneered by Har-Gobind Khorana in the 1950s.

Why is it difficult to make oligos longer than 200nt via direct synthesis?

It is difficult to make oligos longer than 200nt long through direct synthesis as full length product synthesis drops exponentially as length increases. The more chemical reactions that must be done, the greater the rate of error and contamination.

Why canā€™t you make a 2000bp gene via direct oligo synthesis?

Error accumulation as mentioned in previous answer.

šŸ§¬ Homework Question from Dr. George Church

Choose ONE of the following three questions to answer; and please cite AI prompts or paper citations used, if any. What are the 10 essential amino acids in all animals and how does this affect your view of the ā€œLysine Contingencyā€?

The ten essential amino acids in all animals are

  • Arginine
  • Histidine
  • Isoleucine
  • Lucine
  • Lysine
  • Methionine
  • Phenylalanine
  • Threonine
  • Tryptophan
  • Valine

The Lysine Contingency is codswallop because even if dinosaurs were not able to naturally produce endogenous lysine, they could get it from food sources! Humans canā€™t even produce it and must get it from their diet.