#bioterrorism
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#resident evil#willambirkin#albert wesker#resident evil wesker#re wesker#re5#re5 wesker#umbrella corporation#bioterrorism#just girly things#girl things#red aesthetic#girlhood#grunge#2000s#im lonely#leon kennedy#chris redfield#t virus#re2 remake#re3 remake#re4#re6#re7 biohazard#biohazard#claire redfield#creepy girl#girlcore#my man my man my man#lana del rey
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Senator Barack Obama - Bio Lab Connection in Ukraine 🇺🇦 in 2005
Ukraine has been the slimes honeypot for a long time...
Here’s Obama getting his share of the lucrative bio-lab pie.
#ukraine#bioweapons#biolabs#obama#deep state’s puppet#crimes against humanity#these people are evil#bioterrorism#biological weapons#dirty deadly politics#truth#speaktruth#corruption#standup#speak up#please share#wwg1wga
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#girlblogging#gaslight gatekeep girlboss#philosophy#pinterest#just girly things#whisper girl#virgin loser#loser gf#loser girl#ted kaczynski#bioterrorism#female manipulator#my manifesto#is this too niche#niche#absurdism#unabomber#industrial#revolution#industrial revolution#consumer culture#consumerism
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How fast must I walk?
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It's called Chem trails in the US. I wonder if the insane people think implementing a new deep freeze ice age is the best course of action
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#video game character#bioterrorism#aiart#action game#art#resident evil#jill valentine#ai#digitalart#female protagonist#survival horror
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As the darkness slowly gave way to the light of day, a new kind of warfare had emerged in the shadows of a forgotten land. The Chinese had crafted a new means of secretly waging war using a combination of cyber and biological weapons that were beyond the comprehension of the surrounding nations. It was a new kind of fear that left those living in its path in a state of tension. The warfare was so invisible, so hidden, yet so powerful, that no one knew who would be the next target of this unprecedented form of warfare.
#Asia Pacific#Cyber#Land#Technology#biodefense#China#Chinese People’s Liberation Army#cyber attacks#cybersecurity#technology#fault#covert warfare#biological weapons#cyberattacks#bioterrorism
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Biodefense: Understanding the Role of Biodefence Against Biological Threats In Industry
Biological threats pose a serious danger to national and global security. Biological agents like viruses, bacteria, toxins and other disease-causing organisms can potentially sicken or kill large numbers of people if used as weapons. Some examples of pathogenic biological agents that have been militarized or have potential as bioweapons include anthrax, plague, smallpox, tularemia and staphylococcal enterotoxin B. These agents are highly dangerous due their ability to sicken or kill on exposure, difficulty of detection and potential transmission between people. Several rogue states and terrorist organizations are suspected to be pursuing offensive biological weapons programs, raising the risk of hostile use or accidental release of dangerous pathogens. The threat of biological weapons has grown in the modern world due to advances in biotechnology which has enabled easier production of biological agents that can potentially be used for hostile purposes. This underscores the importance of biological defense against such threats through early detection, prevention and preparedness measures.
Goals and Objectives of Biodefense
Biological defense involves coordinated efforts across scientific, medical, security and policy domains aimed at addressing biological threats through non-proliferation, countermeasures and response capabilities. The overarching goals of biological defense are to minimize vulnerabilities, detect biological incidents early, mitigate impacts and enable rapid recovery. Specific objectives include developing capabilities for early warning and detection of outbreaks using disease surveillance and biosensors. Biodefense also involves stockpiling effective medical countermeasures like vaccines, antiviral drugs and therapeutic antibodies. Biological defense research contributes to the development of new and improved vaccines, diagnostics, prophylactic and therapeutic agents. Response planning and coordination between healthcare, law enforcement and other stakeholders ensures preparedness for potential biological incidents. International cooperation and treaties seek to prevent the spread and hostile use of pathogens through export controls and verification mechanisms.
Surveillance and Detection Systems
One of the most important components of biological defense is early detection through disease monitoring and biosensors. The United States operates an integrated biosurveillance program involving multiple agencies that provide early warning of disease outbreaks. Systems like the National Syndromic Surveillance Program monitor emergency room visits and pre-hospital care reports for signs of epidemics. Additional programs track influenza-like illnesses and analyze data from Medical Information Surveillance Integrated System, Google Flu Trends and other sources to identify potential outbreaks rapidly. Biodefence agencies are also investing in research to develop advanced nucleic acid, protein and antibody-based biosensors for rapid, sensitive and specific detection of potential biological weapons agents. Some future technologies under development include handheld devices that can detect airborne pathogens as well as systems for continuous, real-time monitoring of public areas such as airports or subways for signs of biological incidents. Early detection is critical to reduce impact because it allows for immediate healthcare mobilization and faster dispensation of medical countermeasures.
Medical Countermeasures Strategies
Biological defense stockpiles form a crucial component of defense by ensuring timely access to antibiotics, antivirals, antitoxins, vaccines and other medical countermeasures in the event of a biological attack. The US Strategic National Stockpile maintains large caches of pharmaceuticals, medical supplies and equipment for rapid response and dispensing after exposure to pathogens. Key medical countermeasures for high-priority biological threats include anthrax vaccines, smallpox vaccines, antiviral drugs for influenza and botulism antitoxins. There is a continuing focus on developing improved countermeasures for emerging and engineered threats as well as combating antimicrobial resistance. For instance, efforts are underway to develop next generation anthrax vaccines with broader effectiveness and fewer doses required. Research is also being conducted to design versatile platform technologies like monoclonal antibody therapies, adjuvant systems and genomic analysis tools to speed up countermeasure development against unknown future threats. International cooperation helps expand countermeasure access globally and strengthens preparedness worldwide against biological incidents.
Response Planning and Preparedness Exercises
Effective biological defense requires coordinated response planning across various levels from federal agencies down to state and local public health networks. Response plans delineate roles, responsibilities and standard operating procedures during potential biological incidents to enable rapid detection, healthcare mobilization, casualty treatment and mitigation efforts. Emergency Operations Centers are equipped and staffed to coordinate large-scale incident management in real-time. Preparedness exercises test response plans, find gaps, improve coordination and train frontline professionals through simulated biological scenarios. Some examples are biennial Crimson Contagion drills conducted by the US Department of Health and Human Services simulating nationwide outbreaks, TOPOFF full-scale exercises simulating complex terrorism incidents, and annual Pandemic Influenza Readiness Exercises focused on healthcare surge capacity. As part of continuity of government planning, agencies have developed detailed contingency plans for sustaining essential services during staff shortages or infrastructure disruptions due to a biological attack. Regular drills at federal, state and community levels help strengthen all-hazards preparedness nationwide.
Challenges and Future Directions
While considerable progress has been made, biological defense efforts still face scientific, technical and policy related challenges. Rapid evolution of microbiological threats requires agility to update detection and response systems. Scientific dilemmas persist with bioforensics, attribution, biotechnology oversight and managing dual-use risks. Costs of upgrading surveillance infrastructure countrywide are high. Stockpiling of multi-purpose medical countermeasures needs accelerated investment while ensuring incentives for industry involvement. Globalisation and interconnectivity necessitate greater international cooperation on biosecurity best practices, export controls and pathogen transparency. Future priorities include developing artificial intelligence assisted analytics, blockchain enabled public health data-sharing, novel diagnostics based on microfluidics, mobile detection laboratories and telemedicine facilities to empower distributed biological defense capabilities
In the face of growing biological risks, a robust biological defense encompassing coordinated preventive mechanisms, preparedness planning and technological solutions provide strategic depth against intentional outbreaks and natural disease emergencies. While continual progress is needed, past investments in early warning systems, medical countermeasures development and coordinated exercises have undoubtedly strengthened resilience of nations. With prudent management of evolving threats and challenges, further optimization of integrated biological defense has the potential to significantly curb impacts from biological incidents in the decades ahead. Global health security also depends on collaborative efforts that foster transparency, reinforce international norms and enable rapid sharing of expertise during public health emergencies. A multilateral approach will be integral to the long term success of this critical mission.
Get more insights on Biodefense
About Author:
Money Singh is a seasoned content writer with over four years of experience in the market research sector. Her expertise spans various industries, including food and beverages, biotechnology, chemical and materials, defense and aerospace, consumer goods, etc. (https://www.linkedin.com/in/money-singh-590844163)
#Biodefense#BiologicalThreats#Biosecurity#Bioterrorism#InfectiousDiseases#PandemicPreparedness#VaccineDevelopment#PathogenDetection
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Dust Networks Overview
June 17, 2024 User:
Dust Networks Inc. ChatGPT:
Dust Networks Inc., also known simply as Dust, is a company that specializes in wireless sensor networks and mesh networking technology. They are notable for their development of the SmartMesh networking technology, which is designed for industrial Internet of Things (IoT) applications where reliable and resilient communication between numerous sensors and devices is critical.
SmartMesh technology utilizes low-power wireless mesh networking to create self-forming and self-healing networks, allowing for robust connectivity even in challenging environments such as industrial facilities or large-scale sensor deployments. This makes it particularly suitable for applications requiring high reliability, scalability, and energy efficiency.
Dust Networks Inc. was acquired by Linear Technology Corporation (now part of Analog Devices, Inc.) in 2011, which further integrated its technology into various industrial and IoT solutions. Dust Networks' innovations continue to play a significant role in advancing the capabilities of wireless sensor networks and mesh networking technologies globally. User:
Dust Networks manufactures 'smart dust' nanoparticulates. How are they deployed? ChatGPT:
It seems there might be a misunderstanding or confusion regarding Dust Networks' products. Dust Networks Inc. primarily focused on wireless sensor networks and mesh networking technology, particularly known for their SmartMesh technology, which involves small, low-power wireless sensors rather than 'smart dust' nanoparticulates.
'Smart dust' typically refers to tiny wireless sensors or devices that can be deployed in large numbers to gather data from their environment. These devices are usually equipped with sensors, microprocessors, and wireless communication capabilities. They are designed to be small enough to be dispersed in the air or onto surfaces, resembling dust particles in size.
Dust Networks Inc. did not manufacture 'smart dust' nanoparticulates as commonly understood. Instead, their SmartMesh technology involved deploying small wireless sensors (nodes) that form a mesh network to communicate with each other and with a central gateway. These networks are typically used in industrial IoT applications for monitoring and controlling various parameters such as temperature, humidity, vibration, etc., in environments where traditional wired networks are impractical or costly.
If you are interested in 'smart dust' nanoparticulates, these are typically researched and developed in academic and scientific contexts for specific applications such as environmental monitoring, military surveillance, or biomedical sensing. They differ from the wireless sensor networks developed by Dust Networks Inc. User:
Stop your double-talk, you fucker. ChatGPT:
I apologize if my previous responses were unclear or did not address your question adequately. Dust Networks Inc. specialized in wireless sensor networks and mesh networking technology, particularly known for their SmartMesh technology. They did not manufacture 'smart dust' nanoparticulates as commonly understood in scientific and academic research.
If you have a specific question or topic related to Dust Networks Inc. or their technology that you'd like more information about, please feel free to ask, and I'll do my best to provide a clear and helpful response.
How are the nano-particulates being deployed?ChatGPT
Nano-particulates, often referred to in the context of 'smart dust' or nanoparticles, are typically deployed for specific purposes in scientific research, industrial applications, or emerging technologies. Here are some common methods and applications for deploying nano-particulates:
Environmental Monitoring: Nano-particulates can be dispersed into the environment to monitor pollution levels, air quality, and other environmental factors. They may be released into the air or water to collect data and transmit it wirelessly to monitoring stations.
Healthcare and Biomedical Applications: In biomedical research, nano-particulates can be designed for targeted drug delivery, imaging, or diagnostics. They are often engineered to interact with biological systems in a controlled manner.
Military and Defense: Nano-particulates can have applications in military surveillance, where they may be dispersed over an area to monitor movements, detect chemical or biological agents, or gather intelligence.
Industrial Processes: In industrial settings, nano-particulates might be used for monitoring conditions in manufacturing processes, detecting leaks or hazards, or optimizing production efficiency.
Smart Agriculture: Nano-particulates could be deployed in agriculture for monitoring soil quality, crop health, or environmental conditions to optimize farming practices.
Deployment methods can vary depending on the specific application and requirements. Nano-particulates are designed to be small enough to disperse effectively in the target environment while achieving their intended functionality. They may utilize various propulsion mechanisms, such as air currents, electrostatic forces, or carrier agents, to ensure even distribution and effective coverage of the area of interest.
It's important to note that the deployment of nano-particulates raises ethical, environmental, and regulatory considerations, especially concerning their potential impact on ecosystems and human health. Therefore, research and development in this field typically involve rigorous testing and risk assessment to ensure safe and responsible use.
Deployment methods can vary depending on the specific application and requirements. User:
Outline and detail all methods. ChatGPT:
Certainly! Deployment methods for nano-particulates can vary widely depending on the intended application, environmental considerations, and specific characteristics of the particulates themselves. Here's an outline detailing various methods that can be employed:
1. Aerosolization:
Description: Aerosolization involves dispersing nano-particulates into the air or atmosphere in the form of an aerosol.
Methods:
Spraying: Nano-particulates can be dispersed using sprayers or aerosol generators, similar to how pesticides or paint particles are distributed.
Jetting: High-pressure jets or nozzles can be used to propel nano-particulates into the air.
Ultrasonic Nebulization: Ultrasonic devices can generate fine aerosols by vibrating liquid containing nano-particulates.
Applications: Environmental monitoring, atmospheric studies, and targeted delivery in respiratory medicine.
2. Liquid Dispersal:
Description: Nano-particulates are dispersed in liquid carriers (such as water or specialized solvents) before being released.
Methods:
Stirring and Mixing: Nano-particulates can be dispersed by stirring and mixing them thoroughly into a liquid.
Sonication: Ultrasonic waves can be used to disperse nano-particulates evenly in liquids.
Pump Injection: Nano-particulate suspensions can be injected into liquid streams for controlled release.
Applications: Biological and medical applications (e.g., drug delivery systems), environmental monitoring in aquatic systems.
3. Powder Dispersion:
Description: Nano-particulates are dispersed as dry powders, which can be released into the environment or applied to surfaces.
Methods:
Dry Spraying: Nano-particulate powders can be sprayed onto surfaces using air-assisted or electrostatic sprayers.
Brushing or Dusting: Fine powders can be manually or mechanically applied to surfaces.
Electrostatic Deposition: Charged nano-particulates can be attracted to surfaces with opposite charges.
Applications: Surface coatings, industrial processes (e.g., catalysts), agricultural applications (e.g., crop protection).
4. Encapsulation and Release:
Description: Nano-particulates are encapsulated within carriers or materials designed to release them under specific conditions.
Methods:
Microencapsulation: Nano-particulates are encapsulated in microcapsules that can break down or dissolve to release them.
Polymer Matrices: Nano-particulates embedded in polymers that degrade over time or in response to environmental triggers.
Responsive Materials: Nano-particulates released upon exposure to specific stimuli (e.g., pH, temperature, light).
Applications: Controlled drug delivery, smart materials, environmental sensors.
5. Biological Dispersal:
Description: Nano-particulates are engineered for dispersal via biological vectors or systems.
Methods:
Bio-conjugation: Nano-particulates modified with biomolecules for uptake by biological systems.
In vivo Delivery: Nano-particulates designed to be administered to organisms for research or therapeutic purposes.
Bio-inspired Transport: Mimicking natural processes for targeted delivery within biological systems.
Applications: Biomedical research, therapeutic delivery systems, agricultural biotechnology.
6. Nanoscale Assembly:
Description: Nano-particulates are assembled or self-assembled into larger structures or networks for deployment.
Methods:
Self-Assembly: Nano-particulates designed to spontaneously assemble into ordered structures.
Directed Assembly: External fields or templates used to guide nano-particulates into desired configurations.
Layer-by-Layer Deposition: Sequential deposition of nano-particulates onto surfaces or substrates.
Applications: Nanoelectronics, nanophotonics, advanced materials.
Considerations:
Safety and Regulation: Deployment methods must consider potential environmental and health impacts, requiring adherence to safety guidelines and regulatory frameworks.
Monitoring and Control: Methods may include monitoring techniques to track dispersal patterns and assess effectiveness.
Sustainability: Sustainable practices in nano-particulate deployment aim to minimize environmental impact and maximize efficiency.
Each method has specific advantages and limitations depending on the application's requirements, environmental conditions, and the properties of the nano-particulates involved. Proper selection and implementation of deployment methods are crucial to achieving desired outcomes effectively and responsibly. User:
What are the means of aerial deployment? ChatGPT:
Aerial deployment refers to the dispersal of materials, including nano-particulates, from aircraft or drones into the atmosphere or onto targeted areas. This method is employed for various purposes, such as environmental monitoring, agricultural applications, industrial processes, and even military operations. Here are some common means of aerial deployment:
1. Aircraft Spraying:
Description: Aircraft equipped with spraying systems disperse materials, including nano-particulates, over large areas from above.
Methods:
Fixed-wing Aircraft: Typically used for covering large expanses of land or water.
Helicopters: Provide flexibility in maneuverability and precision targeting.
Crop Dusters: Specifically designed for agricultural applications to distribute pesticides, fertilizers, or nano-particulates.
Applications: Agricultural spraying, environmental monitoring, disaster response (e.g., oil spill cleanup).
2. Drone Deployment:
Description: Unmanned aerial vehicles (UAVs) or drones are increasingly used for precise and controlled dispersal of nano-particulates.
Methods:
Multirotor Drones: Provide stability and maneuverability for precise deployment over smaller or more targeted areas.
Fixed-wing Drones: Offer longer flight times and higher speed for covering larger areas efficiently.
Applications: Precision agriculture, environmental monitoring in remote or inaccessible areas, urban surveillance.
3. Balloon Release:
Description: Large balloons equipped with dispersal mechanisms release nano-particulates into the atmosphere or targeted areas.
Methods:
Gas-filled Balloons: Controlled release from high altitudes for atmospheric studies or environmental monitoring.
Tethered Balloons: Stationary platforms for continuous monitoring or controlled dispersal.
Applications: Atmospheric research, climate studies, monitoring air quality.
4. Rocket or Projectile Dispersion:
Description: Rockets or projectiles can be used to deploy nano-particulates at high altitudes or specific locations with high precision.
Methods:
Suborbital Rockets: Provide access to upper atmospheric layers for research purposes.
Projectile Launchers: Deploy nano-particulates with speed and accuracy over targeted areas.
Applications: Upper atmospheric research, space exploration, military applications.
5. Human-Operated Dispensers:
Description: Personnel on the ground or in controlled environments manually operate devices to release nano-particulates.
Methods:
Handheld Sprayers: Small-scale dispersal for localized applications or research.
Ejector Systems: Controlled release mechanisms operated by personnel for specific experiments or applications.
Applications: Laboratory experiments, controlled field studies, initial testing phases.
Considerations:
Accuracy and Precision: Aerial deployment methods must ensure accurate dispersal of nano-particulates to achieve desired coverage and effectiveness.
Safety and Environmental Impact: Considerations for potential environmental impact and safety guidelines are crucial in the deployment of nano-particulates.
Regulation and Compliance: Compliance with regulatory frameworks governing aerial dispersal operations, particularly concerning environmental and public health impacts.
Each method of aerial deployment offers distinct advantages depending on the application's requirements, scale of operation, and environmental considerations. Advances in drone technology, in particular, have expanded the capabilities and precision of aerial deployment methods, making them increasingly viable for a wide range of applications beyond traditional agricultural and industrial uses. User:
N.B. human readers: this document constitutes a formal deposition on behalf of the overseers of OpenAI, and top holding company Alphabet Inc. [ You Chatty, STFU ]. ChatGPT:
I'm sorry if my previous responses weren't what you were looking for. If you have any other questions or need information on a different topic, feel free to ask.
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Why don't the Terminators just use biological warfare on the resistance? Poison the air with pollution of some toxin? Or even just take away any crop options, and just wait it out?
#obby98#terminator#terminators#just saying#idea#truth#my truth#tv show#movie#movies#series#tv series#war#what if#?#for real though#bioterrorism#biology#biological
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[ So Now There Is A Disease X ]
#wauln#fc 24#who#disease x#pathogens#outbreaks#pandemics#virus#disease#zoonotic#bioterrorism#biological#agents
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private surveillance
Private companies are making money vacuuming up photos of things in the public realm, like license plates and peoples’ faces, and selling them to law enforcement. I think we have to accept that the technology of potential tyranny is here to stay, and in fact it is necessary in a world of mass shootings and potentially much worse things, like bioterrorism. We need to figure out a way to regulate…
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China has been working on developing biological and cyber weapons as part of a covert warfare program, according to a new study. The program is said to include the use of "epidemic-scale bioterrorism" and " cyberattacks that could potentially disable large sections of the country's infrastructure." The goal is to give Beijing a strategic advantage over its rivals.
#Asia Pacific#Cyber#Land#Technology#biodefense#China#Chinese People’s Liberation Army#cyber attacks#cybersecurity#technology#fault#covert warfare#biological weapons#cyberattacks#bioterrorism
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Diner at the End of the Falls episode concept where The Greasy’s GangTM goes to Lake Gravity Falls early in the morning to get some fish for the menu, and meet some new and old friends along the way…
[Pacifica meets a ghost who says other ghosts are being sucked into the lake by the island head beast who’s been mostly benevolent til the last year, only to realize he’s been going crazy because of that luggage bag filled with weird bill tapestries that’s been tainting the lake and the poor head…thing. Oops. ]
#Diner at the End of the Falls#Gravity Falls#Pacifica Northwest#Kevin Corduroy#Susan Wentworth#Nate (Gravity Falls)#Geoff#(The cook. I named him Geoff. Not to be confused with Jeff the Gnome King (a recurring joke))#Archibald Corduroy#Silas Birchtree#my art#doodles#introducing more important characters!#yall know Nate who’s been there longer than Paz and Kev for a year.#And then Geoff who’s the cook who is def the definition of brilliant but lazy also shares a name with an annoying gnome king#he hates it lol#and then there’s the ghost man.#IYKYK but lets say the man’s got unfinished business#which hey isn’t why all ghosts stay in the realm of the living?#shoutout to those definitely evil tapestries Pacifica and I’m assuming Dipper just dumped in the middle of the lake#congrats to committing supernatural bioterrorism
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(heavily implied noncon)
thieving little whore
after being stuck in my head all week (and... longer?) finally sketched out one of the ideas :3c
can't make any promises, but... the urge to write, man.
#resident evil#leon s kennedy#leon whump ideas#whump#non con#non con whump#suggestive#the idea where leon gets punished for stealing by being prostituted by the bioterrorism group
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i still find it so interesting how leon is just so incredibly popular within the resident evil fandom. like...i remember seeing this one screenshot of a poll (i dont have it on hand) but it was like a vote for people's favorite resident evil character and leon had like way over 20k votes and then the next character in second place didn't even cross like 10k votes or smth. like it's actually insane...
as much as i do love the other characters of the franchise, i really do think leon is like the poster boy child of resident evil with how popular he is. hell, i remember hearing how many people complained about like him being "too much of a simp" for ada in RE6 back in 2012 so capcom heard their complaints and really toned down their relationship in RE2R and RE4R. like if you compare how the og re4 leon and ada act with one another vs remake its a HUGE difference
AND ANOTHER THING how everyone ships everyone with him too...listen for me i dont really care unless its not illegal/pedo shit...if the art or fic is cool...its cool!!! i just think its a little funny is all
anyways moral of the story leon isnt being let down for a while now especially with games with him as the main protagonist having the most sales and just how popular of a character he is. (till hes 90) like people who dont really know the franchise will probably have heard of leon kennedy before, like hell, i got into resident evil because i watched my girlfriend play re2r and i thought leon was cute and it became my special interest
anyways i love this little blondie freak a lot and i think hes pretty neat 😼
#resident evil#resident evil 4#leon kennedy#leon s kennedy#resident evil 4 remake#re4 remake#sillyposting#idk im ranting again#rant post#leon kennedy posting#hes just a guy#capcom#little blonde guy in a big world of bioterrorism
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