MedBlock Protocol (MBP） Deeply cultivate medical artificial intelligence and lead smart medical innovation

MBP token ........................................................................................................................................ 3 1. Project vision ............................................................................................................................... 3 2. Project background ....................................................................................................................3 Chapter 1 Market industry analysis ..................................................................................... 4 1. Current situation of the health care industry ................................................................. 4 1. Industry pain points ....................................................................................................................7 Chapter 2 Project Introduction-MBP Token .................................................................... 10 2.1 MBP tokens are designed and original worldwide .................................................... 10 2. 6 MedBlock Protocol Ecosystems ................................................................................. 17  Real-time diagnosis ....................................................................................................... 21 Chapter 3 MedBlock Protocol Value realization .................................................................... 23 3.1 Overview of infrastructure ............................................................................................ 23 3.2 Develop service layer .................................................................................................... 23 3.3 User service layer ............................................................................................................25 3.4 MedBlock Protocol Blockchain underlying services ................................................ 27 4.1 Health services ............................................................................................................... 29 4.2 Medical services ............................................................................................................. 31 4.4 Medical insurance and mutual aid .............................................................................. 33 5.2 Development steps ........................................................................................................ 36 Chapter 6 Team Introduction ............................................................................................. 36 6.1 Core team ........................................................................................................................ 37 7.1 Total issuance .................................................................................................................. 41 7.2 Launch programme ........................................................................................................ 41 7.3 Token acquisition path ................................................................................................. 42 Chapter VIII Disclaimer ................................................................................................................ 43 Appendix II References ............................................................................................................... 44

MBP token 1. Project vision As technology advances rapidly and global health needs continue to evolve, the healthcare industry is facing unprecedented challenges and opportunities. By 2025, the global healthcare sector will be further influenced by multiple factors including artificial intelligence (AI), digital transformation, population aging, and health equity. We will delve into the current state and future trends of the global healthcare industry in 2025, explore the main challenges and opportunities it faces, and provide an outlook on its future development. We are dedicated to building a new healthcare ecosystem alliance. By applying blockchain technology, we connect consumers, hospitals, doctors, and service marketers, creating a transparent, open, decentralized, and integrated healthcare system. This reduces marketing costs and, in turn, lowers expenses. Through the issuance of MBP tokens, we ensure the safety and value preservation of consumer funds, enhancing consumer trust. This helps to legitimize healthcare and attract more potential consumers. 2. Project background The global healthcare market is expanding rapidly with economic development, currently in a period of high-speed growth. However, healthcare institutions face issues such as severe homogenization, excessive marketing, and low consumer trust. At the same time, there is a shortage of excellent doctors, and there is a trend of outstanding doctors starting their own businesses. How to sign up excellent doctors, find good suppliers of medical equipment materials, and ensure that these excellent doctors and target consumers can connect freely and without barriers, while protecting the rights and satisfaction of all parties involved, is the problem we need to solve.

Chapter 1 Market industry analysis 1. Current situation of the health care industry With the rapid development of medical technology, the field of health and wellness is seen as the most promising direction for technological innovation over the next decade. Currently, health and medical big data covers a wide range of areas, including public health, clinical research, disease diagnosis, and industry governance. However, the types of applications in practice are not diverse enough or deep enough. The rise of artificial intelligence technology, which leverages the inherent advantages of medical big data, is poised to become a significant trend in the near future. The healthcare industry has had a profound impact on the lives of people all over the world. It has penetrated into all aspects of life from the market situation, industry services, service conditions and market scale. Therefore, market research on the healthcare industry is conducive to a deeper understanding of the characteristics of the industry, providing support for investment in the industry and providing better products and services for citizens.

1.2 The size and complexity of the U.S. healthcare industry The healthcare industry in the United States is one of the largest and most complex medical systems globally. In 2020, healthcare accounted for 18% of GDP, highlighting its significant role in the economy. This sector not only benefits from a robust system of medical research and development but also works closely with higher education and the technology industry. The aging population and the trend of the baby boomers becoming older further drive the sustained strong demand for healthcare services. 1.3 Main economic characteristics and market dynamics The healthcare industry has some unique economic characteristics. First, the demand for medical services is highly price inelastic, meaning that even if prices rise, demand does not significantly decrease. Second, there is significant information asymmetry in the healthcare sector, with the information gap between patients and providers potentially leading to principal-agent problems. Additionally, entry barriers in the healthcare industry are high, including professional licenses, regulations, intellectual property protection, and substantial R&D costs. These features make the market dynamics of the healthcare industry very complex, affecting the operations and competition of companies within the industry. 1.4 The impact of government intervention and policy on the healthcare industry Government intervention in the healthcare sector is both common and necessary. Given the public nature and social importance of healthcare services, the government ensures basic public health protection through legislation, funding, and

direct involvement in service delivery. For example, in the United States, the government provides extensive health insurance coverage for a large number of citizens through programs like Medicare and Medicaid. Additionally, the government influences the operation of the healthcare industry through legislation and regulation, such as the implementation of the Affordable Care Act, which aims to expand health insurance coverage and reduce medical costs. However, government intervention also introduces policy uncertainty, potentially impacting investment and operations in the healthcare industry. 4. The global healthcare market has huge growth potential Health is an eternal theme for human beings and an important symbol of social progress. Health has become the basic goal of peoples life in the new century. The health industry has huge market potential, and Paul Pitzer, a famous American economist, once called it the "fifth wave of global wealth" after the IT industry.

In the healthcare industry, especially in medical device manufacturing, data management and processing are crucial. MedBlock Protocol offers an efficient and flexible solution that helps healthcare institutions quickly develop and deploy customized applications. For example, medical device companies can use MedBlock Protocol to build internal management systems, streamline processes, and improve efficiency. Additionally, MedBlock Protocol supports seamless integration with external systems such as those in the global medical device industry, ensuring data accuracy and consistency. In this way, healthcare institutions can better manage key data such as patient information and equipment maintenance records, thereby enhancing overall operational efficiency. Other countries healthcare penetration rates differ significantly from those in the United States, leaving vast room for growth. In 20 24, the healthcare market penetration rate in other countries is less than 0.5%, while that in the U.S. is around 5%. The healthcare market penetration rate in other countries is far below that of mature markets. Considering the potential healthcare demand and large population base, there is enormous room for imagination in other countries healthcare markets. 1. Industry pain points For healthcare institutions, the high costs of re-marketing and channel acquisition are a common pain point in the industry. Methods for acquiring customers include referrals from beauty salons and other intermediaries, search engine advertising, and offline events. These marketing expenses account for as much as 50% of total revenue, significantly squeezing the profit margins for doctors and healthcare institutions. The prices of medical services remain high, which ultimately passes on to consumers. Additionally, the lack of transparency and regulatory oversight makes it difficult for consumers to verify the qualifications of institutions and doctors, leading to concerns about surgical safety and postoperative outcomes. This results in a loss of confidence in the healthcare industry among consumers.

2. —— In contrast to the relatively fast growing health care market, there is a scarcity of qualified plastic surgeons who provide health care services. •Currently, there are over 200,000 doctors in the healthcare industry, but fewer than 90,000 of them are qualified plastic surgeons. Among these 200,000 practicing physicians, more than half have transitioned from medicine to healthcare, requiring extensive clinical experience to reduce error rates and enhance their knowledge of health insurance; however, 5-10% of healthcare professionals lack professional qualifications and engage in illegal medical practice after short-term "training," leading to frequent medical accidents and making it difficult for consumers to seek redress. •The medical service is under the responsibility of the attending physician, and it takes more than ten years to train a medical attending physician. Due to the scarcity of head physicians, it is common for doctors to practice beyond their grade, which poses great risks to plastic surgery. As a scarce resource, high-quality doctors are bound to be the "struggle" object of various medical and health care institutions. How to make doctors flow in the industry and play a greater role is the pain point of the medical and health care industry. 3. The healthcare industry chain is divided into upstream, midstream, and downstream segments. Upstream includes manufacturers and distributors of healthcare equipment and consumables; midstream comprises healthcare institutions; downstream consists of consumers. Third-party support services such as marketing and payment are bridging the midstream and downstream segments.

As mentioned earlier, marketing costs "overwhelm" healthcare institutions, but for these institutions, healthcare equipment and consumables also constitute a significant portion of their expenses. Traditional healthcare institutions have to negotiate and compare each vendor for equipment procurement or consumable purchases, which is inefficient and makes it difficult to select suitable suppliers. 4. Difficulties in consumer rights protection. When consumers sign agreements with healthcare institutions, these agreements are not always clear and may contain ambiguous clauses or loopholes, making it difficult for consumers to protect their rights later on. Moreover, consumers have no channels to evaluate the service provided by doctors, nurses, and staff throughout the process.

Chapter 2 Project Introduction-MBP Token 2.1 MBP tokens are designed and original worldwide MedBlock Protocol is the worlds first healthcare service platform built on blockchain technology, developed by the MedBlock Protocol team. MedBlock Protocol leverages blockchain technology (electronic records, trusted evaluations, digital assets, cryptographic algorithms, peer-to-peer transmission, smart contracts, AI) to address multiple challenges faced by healthcare institutions, such as opaque doctor information and rampant illegal medical practice; uneven quality of products and services, unregulated consumables, and counterfeit goods; false advertising and opaque service prices; limited marketing channels and increasing customer acquisition costs; insufficient regulatory oversight, and difficulties in consumer rights protection. 1) The application of ARTIFICIAL intelligence in healthcare will accelerate The rapid development of artificial intelligence technology is transforming various aspects of healthcare. From diagnosis to treatment and patient management, the application of AI is enhancing the efficiency and quality of medical services. According to data, it is estimated that by 2025, the use of AI in healthcare will save global healthcare systems up to $360 billion in costs. This trend is not limited to the United States; healthcare institutions worldwide are actively exploring the application of AI technology. The main application areas of AI include: - Disease prediction and diagnosis: AI can help doctors predict disease risk and make early diagnoses more accurately by analyzing large amounts of medical data. For example, some AI models have been able to identify early signs of cancer in imaging tests with greater accuracy than traditional methods.

-Personalized treatment plans: AI can develop personalized treatment plans based on patients health data and history. This concept of precision medicine is becoming a reality, especially in chronic disease management and cancer treatment. -Improve patient experience: AI-driven chatbots and virtual assistants are improving communication between patients and healthcare providers, providing real-time consultation and appointment services, thus improving the overall medical experience of patients. Despite the potential of AI, medical institutions need to pay attention to data privacy and security issues in the implementation process to win the trust of patients. 2) Digital transformation will be the core driver of industry development Digital transformation is a significant trend in the future development of healthcare. With the widespread adoption of electronic health records (EHRs), telemedicine, and mobile health applications, the way medical services are delivered is undergoing fundamental changes. According to market research, the global healthcare digitalization market is expected to reach $62 billion by 2026. The main manifestations of digital transformation include: - Telemedicine adoption: Telemedicine usage has increased significantly during the pandemic and is expected to continue after 2025. Patients can consult with doctors via video conferencing, reducing the time and cost of medical visits. -Interoperability of health data: Through digital platforms, medical institutions can achieve data sharing and integration, improving the continuity and efficiency of medical services. This interoperability not only helps improve the quality of diagnosis and treatment, but also provides important support for public health monitoring.

-Improved patient self-management: With the popularity of health monitoring devices, patients can better manage their health. Tools such as smart wristbands and health apps allow patients to monitor their physiological indicators in real time and share data with healthcare providers. 3) Aging populations will drive long-term care demand by 0.0% Global population aging is one of the major challenges facing the healthcare industry. According to UN projections, the global population aged 65 and over will reach 1.2 billion by 2025, accounting for about 16% of the global population. This change will significantly increase the demand for long-term care services. The main effects of aging include: - Increase in chronic diseases: The incidence of chronic diseases is higher among the elderly population, and the medical system needs to provide more medical resources and nursing services for this group. This means that medical institutions need to adjust their service mode to meet the special needs of elderly patients. -Rising demand for long-term care services: With the increase of the elderly population, the demand for long-term care services will increase significantly. Governments and medical institutions need to formulate corresponding policies and measures to ensure that the elderly can obtain high-quality care services. -The rise of home care: Many families choose to care for the elderly at home, which has driven the development of home care services. Medical institutions can help family members better care for elderly patients by providing training and support. In the face of the challenges posed by an aging population, MedBlock Protocol needs to respond proactively and innovate service models to meet the growing need for care.

4) Health equity will be a priority in policy development Health equity means that everyone has equal access to health opportunities and resources. As society pays more attention to the issue of health equity, the healthcare industry will pay more attention to eliminating health disparities by 2025. The main manifestations of health equity include: - Policy advocacy: Governments and international organizations will strengthen policy advocacy for health equity and promote the formulation of relevant laws and regulations to protect the health rights of vulnerable groups. -Community participation: Health care institutions will pay more attention to cooperation with communities to promote the implementation of health education and preventive measures to improve public health awareness and self-management ability. -Data transparency: By collecting and analyzing health data, health care institutions can identify health gaps and develop targeted interventions. This data-driven approach to decision-making will help achieve fairer allocation of health resources. Health equity is not only a reflection of social justice, but also an important way to improve the overall health level of society. MedBlock Protocol is also making continuous efforts in this field to promote sustainable development of society. The 2.2 MBP token is groundbreaking MedBlock Protocol is an innovative healthcare platform based on blockchain technology, aimed at addressing multiple challenges faced by the global healthcare industry through decentralized and efficient data management solutions. The revolutionary business model and technological foundation enable seamless data sharing and collaborative development across all aspects of the healthcare sector, tackling current issues in healthcare and promoting its healthy and orderly

development. Consumers can find high-quality doctors; healthcare institutions can quickly target customers, reduce marketing costs, and find suitable suppliers. Introduction to the 2.3 MBP token MBP, the token is the currency issued and used by the MedBlock Protocol platform. The users of this currency are all parties participating in the platform. For consumers, it can be used to pay various medical expenses; for doctors, it can be withdrawn as cash; for suppliers, it can be used to transact with healthcare providers. The MBP token has a hairstyle similar to Bitcoin, based on blockchain technology and mining mechanisms. Due to its lack of third-party centralized control, the issuance quantity and timing are determined by big data calculations, with a fixed total amount, inherently possessing characteristics of value preservation and appreciation. Because of these features, it will inevitably attract a group of consumers and investors, thereby continuously expanding the influence of the platform and its tokens. 2.4 MBP tokens and blockchain matchmaking 1. Quality doctors can circulate on the platform: in traditional healthcare, a doctor can cooperate with only a few hospitals at most, but in the blockchain, doctors from all over can participate in the platform, reach an agreement with MedBlock Protocol, and then cooperate offline. This can make full use of quality doctors resources. Blockchain protects consumer rights: zero-knowledge proofs and blind digital signatures in blockchain. Because of its non-forgery, non-repudiation, and non-traceability, it can help protect consumers privacy and transaction details. At the same time, the unalterable nature of information can prevent healthcare institutions from deceiving consumers. 2. Digital currency in blockchain. Transactions in blockchain use the digital currency issued by it. Digital currency can maintain its value due to its decentralized

characteristics. 3. Credit investigation system refers to the verification of an institutions qualification through certain ways when an individual or institution joins a blockchain platform to ensure its good credit. At the same time, consumers can evaluate the credit of institutions, doctors and service marketers to continuously improve the credit mechanism. 4. The information of suppliers joining the blockchain platform is more transparent —— whether it is product quality or product price, which is conducive to the healthy development of the whole supply industry, and at the same time helps an institution to find a suitable supplier. Innovative features of 2.5MBP tokens 1. The platform system is the core value of MedBlock Protocol. MedBlock Protocol will upload the core value data of the healthcare market to the chain through blockchain technology (encryption algorithm, peer-to-peer transmission, consensus mechanism distributed data block storage technology, smart contract and so on). Doctor data on the chain: MedBlock Protocol The doctor will encrypt and store the whole operation, digitize the doctors skills and experience, cases, and evaluate the quality of health care and user feedback. Artificial intelligence technology will be introduced in the future. MedBlock Protocol Establish electronic files for doctors through blockchain technology, and realize decentralization by using the non-tamperable feature on the chain and consortium community technology to establish a credible doctor selection and evaluation mechanism.

User data on the chain: User reviews and cases are key to breaking down the lack of transparency between doctors and consumers, as well as building trust in buying and selling. Users can view all the information of doctors on the chain. All users information, evaluation, case and other data will be on the chain, and other users can pay to view real cases and evaluations, and the viewed users and corresponding doctors will be rewarded. Medicare data on the chain: The alliance enterprises write product information through MedBlock Protocol to ensure that the supply process of medical insurance drugs and devices on MedBlock Protocol is traceable. Through smart contract, consumers purchased products are bound with their ID information to achieve source locking. service system: All services of healthcare consumption need to be completed offline. Therefore, health care landing becomes an important node of completing the consumption loop. MedBlock Protocol Operate distributed surgery centers worldwide, combine smart contract insurance claims, and artificial intelligence technology to bind users on-chain identities together. Improve the intelligence, technology and standardization of offline surgery implementation, and improve the overall efficiency of the industry. 2. Forming a virtuous cycle: By reducing marketing costs, materials, and healthcare costs, the platform can lower the costs passed on to consumers, attracting more consumers to join. As the platform grows, more high-quality suppliers and doctors will join, and MBP tokens will attract investors. Ultimately, this will form an integrated

healthcare ecosystem that combines supply, service, and finance. 2. 6 MedBlock Protocol Ecosystems 2.6.1 Ecological framework MedBlock Protocol aims to create an intelligent hardware IoT + blockchain + AI smart doctor system platform, becoming a decentralized value platform built on blockchain-based smart contracts. It allows for free data exchange according to smart contracts and leverages the anti-counterfeiting and tamper-proof properties of blockchain to record every transaction and user click. This makes the industrys upstream and downstream chains transparent and efficient, maximizing efficiency and reducing costs for community hospitals and health groups. On one hand, the MedBlock Protocol platform develops user-oriented health management and medical bracelets supported by underlying technologies. On the other hand, it attracts partners to form a supply alliance to enter the platform and provide services to users, including community hospitals, nursing homes, and wellness groups, achieving health management and consulting services for elderly diseases and chronic conditions. By providing these service platforms, relevant user data can be obtained. For individuals, this can form a comprehensive health credit record of all their movements. For stakeholders in the health sector, elderly care industry, and pharmaceutical industry, the formed medical and health data, elderly care data, transaction data, and settlement data can offer marketing recommendations, contributing more comprehensively and reliably to precise marketing with accurate user information.

Healthcare data Pension data Settlement data transaction Health management and consulting services MedBlock Protocol Health management platform Blockchain big Life data Smart Base management Register for Screening of Data Outpatient/hospit nursing institution Health group Base management Old-age care and health 2.6.2 Medical data The platform has established a health monitoring system, through which users physical conditions can be observed to form medical data reports. The health monitoring system primarily observes users medical records and various physiological indicators. By integrating data from community hospitals, it comprehensively monitors users physical conditions and analyzes them to produce health reports. Health monitoring physiclal Detailed Life data Medical test health Image: Health Watch System

2.6.3 Medical credibility In recent years, health data breaches and medical identity theft have occurred frequently, leading healthcare providers to actively seek the most effective ways to ensure personal health information security. The inherent sensitivity of health data, along with factors such as interoperability, patient record matching, and health information exchange, continuously pose challenges to data security. To date, healthcare service providers have exchanged health data through one or more of the following methods: (1) Sending: medical information is sent from one provider of medical services to another; (2) Application: Provide the other party with a medical information application; (3) View: The provider can view the data recorded by other providers systems. Blockchain technology offers a fourth mode of information exchange, ——, which can securely share lifelong medical information among providers. The distributed structure of blockchain can be applied to medical data sharing; its tamper-proof timestamp feature addresses issues of data and device traceability as well as information anti-counterfeiting; its high redundancy and complex multi-private key management advantages resolve security certification deficiencies in current medical information technology. 2.6.4 Medical finance MedBlock Protocol is building a distributed health finance blockchain platform, which reconnects medical institutions, health insurance, doctor groups and other health-related industries based on health medical big data, forming a positive cycle of sports, health, security, medical care and rehabilitation, and creating a medical health finance ecosystem.

MedBlock Protocol employs blockchain technology, forming its three-tier architecture system with "foundation chain, platform, and chain application"; adopts "data on-chain, data assetization, and asset securitization" as the practical approach for MedBlock Protocol finance; and develops four core functions: "health wallet, health bank, health insurance, and health exchange." The "Healthy Wallet" employs a token user incentive mechanism. In terms of insurance, contracts are on-chain; regarding users, user data is on-chain, including health and fitness data, medical check-up data, and medical records; for doctors, articles and videos about healthcare are also on-chain. After all the data is on-chain, users receive tokens as incentives. When physicians articles and videos are clicked by users, they also receive tokens. These tokens can be used to purchase medical insurance, schedule appointments for medical care or health check-ups on the platform, thus completing an ecological loop from token generation to consumption. MedBlock Protocol Connect users, hospitals, doctors and third-party services (insurance, health services, etc.) through Token to make the interaction between doctors and users more efficient, so that the problem of difficult access to medical treatment can be effectively solved. At the same time, MedBlock Protocol uses the incentive mechanism of blockchain technology to help people effectively improve their exercise habits, do a good job in disease prevention and reduce the probability of getting sick, which is also the original intention of MedBlock Protocol to make "health wallet". The "health exchange" is not about trading coins, but about trading health data, such as ones own case data, which an insurance company or pharmaceutical company wants to use and has to pay for, so that institutions can use this data to do better research, especially on major diseases. 2.6.5 Medical culture Creating medical ecosystem application scenarios can foster a positive healthcare

cultural atmosphere for both users and doctors. Doctors, freed from the constraints of hospital frameworks, become independent and flexible individuals in the healthcare market. Through digital and mobile healthcare, they can build their own reputations, promote their therapies, and drive the development of digital and mobile healthcare. This effectively enhances medical characteristics and culture, fostering a harmonious and healthy healthcare cultural environment. 2.6.6 Payment system Compared with the existing traditional payment system, the blockchain technology can bypass the complicated system and directly conduct transactions between the two parties without involving intermediate institutions. Even if part of the network is paralyzed, it will not affect the operation of the whole system. This method has the characteristics of low price and speed, and there is no need for intermediate fees. 2.7 Integration of treatment hardware and Internet of Things  Real-time diagnosis Devices in the Internet of Things can be connected to each other, creating and maintaining a network of knowledge with fully functional feedback and circulation systems that can adapt without the supervision of doctors. For example, we can use the Internet of Things to monitor patients conditions. If devices are interconnected, they can share real-time data and provide timely and accurate feedback when a patients condition worsens. With IoT, doctors have more time to treat more patients, while also monitoring those already receiving treatment in real time. Moreover, the integration of IoT greatly simplifies this process, allowing doctors to monitor patients conditions through representatives like nurses, preventing deterioration and potential risks.  Home surveillance Unlike the Internet of Things, big data collects information from peoples behaviors

and feeds the right data back into the system. The integration of big data in homes is traditionally referred to as automation, such as thermostats and smart bathroom devices. Patients with acute illnesses may require longer-term monitoring by physicians or other personnel. With the help of the Internet of Things, we can set up sensors and blood pressure monitors in patients homes, where they can be monitored and managed. This information does not have to be sent to doctors. It can be stored in the cloud and compared with the patients diagnosis. If the persons condition becomes abnormal, the cloud will send an urgent notification to the doctor. This not only saves a lot of time but also brings better medical prospects, as the cloud monitoring allows for the detection and handling of serious conditions before they worsen. In the near future, by installing biometric monitors at home and connecting them to big data analysis software, it will be possible to monitor ones health in real-time using ordinary people.  Faster response Using the Internet of Things and big data to treat conditions like arthritis can reduce costs. According to estimates, the Internet of Things and big data can significantly lower various costs in the long run. The most obvious is administrative expenses, which often come from routine tasks such as document maintenance and multiple diagnoses.

Chapter 3 MedBlock Protocol Value realization 3.1 Overview of infrastructure MedBlock Protocol adopts a modular and component-based underlying architecture. When users build a blockchain application or a blockchain sub-chain, most components are designed to be assembled and used by referring to each other like Lego blocks. All components support plug-and-play technology, encryption algorithms such as RSA and national cryptography, and users can also expand on it. Storage components and communication components are the fundamental building blocks of all blockchain systems; in terms of communication components, MedBlock Protocol has not only implemented basic P2P networks but also extended the principle communication network and flexible link protocol (for more details, see the technical details section); regarding storage components, MedBlock Protocol has gone beyond ordinary block storage to achieve file storage for world state and block data, as well as relational database storage, to meet institutional users high disaster recovery requirements and high concurrency demands for data queries. In terms of security components, MedBlock Protocol takes identity authentication as an option, which users may need to show their identity authentication information only when running specific blockchain applications; in terms of application components, MedBlock Protocol has provided smart contracts, digital assets, incentive mechanisms and other basic components for creating smart contracts and blockchain applications. 3.2 Develop service layer 3.2.1 Smart contract life cycle management Provides lifecycle management functions for smart contracts, such as creation, invocation, upgrade, and destruction.

Provides the ability to upgrade and migrate data for smart contracts, but must meet the upgrade rules set by the original smart contract. 3.2.2 Smart contract portfolio services A) Create new service functions by combining one or more existing smart contracts. b) Design integrated interfaces to enable users to access multiple blockchain system services. 3.2.3 Smart contract testing service A) Test the functionality of components implemented in the blockchain system to ensure that these components fully and correctly implement service functions. b) Test the component functions implemented in the blockchain system to detect the system security and robustness of these components. c) Ensure interoperability of service function interfaces. B) The test should cover the service deployment nodes in the blockchain system. 3.2.4 Smart contract template service A) The MedBlock Protocol blockchain system adopts the current mainstream virtual machine mechanism in terms of support for on-chain business, and is actively developing other virtual machine implementations that are closer to MedBlock Protocol applications, so as to facilitate the rapid development/customization of on-chain business logic. B) Predefined contract module: The shared-level blockchain system can be used quickly. For some common business scenarios, the shared-level blockchain system

has pre-developed several on-chain business contracts that can be directly used. 3.3 User service layer 3.3.1 Wallet "The wallet" is actually a container for managing keys (including private and public keys). Users can create their own public and private key accounts through the wallet and perform operations such as smart contract calls for digital currency transactions. The public key is used to generate addresses. Users sign transactions with their private keys to prove ownership of the transactions output, and the transaction information is not stored in the wallet but on the blockchain. MedBlock Protocol supports various types of wallets, making it easy for users to import and export digital currencies. 3.3.2 Account The account system under the MedBlock Protocol digital currency framework is a spontaneous or automated accounting system that no longer sets up a "bookkeeping center." Instead, it operates on a public-private key system based on cryptography. Value transfers between accounts are conducted through consensus mechanisms that do not require trust or coordination, binding identity attributes to account attributes. According to the basic protocol, the identity attributes, account norms, and accounting rules of digital currencies are clearly defined to ensure the consistency and immutability of the account system. 3.3.3 Storage MedBlock Protocol Structured storage is used to preserve structured records and maintains synchronization with records on the blockchain. Data is stored permanently in blocks. Blocks are generated sequentially over time and linked together to form a chain, each block recording all transaction information that occurred during its creation period. The data

structure of a block is divided into the Block Header (header) and the Block Body (body). The Block Header links to the previous block and ensures the integrity of historical data through the timestamp feature; the Block Body contains all verified transaction information generated during the blocks creation process. 3.3.4 Privacy protection The privacy module provides encryption contract related services and various privacy solutions. (1) Cryptographic contracts For smart contracts with privacy requirements, encrypted contract solutions are provided. In an encrypted contract, the information within the smart contract is encrypted, and transactions that call the contract are also encrypted. Private transactions use a partial consensus method, and the execution of a private transaction involves two steps: the first step is preprocessing, converting a privacy transaction into a regular transaction [S1 => S2] (where S1 and S2 represent the ciphertext states of the smart contract before and after the transaction execution); the second step is packaging [S1 => S2] as a regular transaction and including it in a block. Encryption contract solutions (2) Privacy solutions Sensitive data is encrypted by AES-256 method through split redundancy and stored independently outside the server to prevent user privacy leakage. Pack into blocks regular way State S1 => State S2 Private transactions

3.4 MedBlock Protocol Blockchain underlying services 3.4.1 Security mechanism In view of the digital asset security problems existing in the digital asset industry, MedBlock Protocol constantly improves its own security mechanism and is committed to providing reliable and guaranteed blockchain sharing services for users. (1) Encrypt data transmission and storage First, the website has a digital signature certificate. Second, the website traffic runs on fully encrypted SSL (HTTPS). Third, wallets (and private keys) are stored using AES-256 encryption. Sensitive data is split and redundantly encrypted using AES-256 and stored independently outside the server. (2) Safety alarm system and real-time monitoring system MedBlock Protocol Install security alarm system and real-time monitoring system on the server to establish high level of server security protection level and effectively prevent serious consequences caused by extreme attack behaviors. 3.4.2 Consensus mechanism Consensus refers to the process in which multiple nodes participate and reach agreement on certain data, behavior or process through interaction of multiple nodes under preset rules. Consensus mechanism refers to the algorithm, protocol and rule that defines the consensus process. There are several main consensus mechanisms: PoH: Historical Proof (Proof of History, PoH) is a cryptographic clock that records the order of events by generating a verifiable time sequence. MedBlock Protocos consensus mechanism inherits the core idea of Solanas PoH by using a continuous one hash function To create a chain of time, which can be verified by anyone, to

ensure the order and timing of events. PoW: It relies on machines to perform mathematical operations to obtain the right of accounting. Compared with other consensus mechanisms, it consumes more resources and has weak regulatory ability. At the same time, every consensus requires the whole network to participate in the operation, so its performance efficiency is relatively low. In terms of fault tolerance, 50% of nodes in the whole network are allowed to fail. PoS: The main idea is that the difficulty of obtaining the right to keep accounts is inversely proportional to the rights held by the node. Compared with PoW, it reduces the resource consumption caused by mathematical operations to a certain extent, and the performance is also improved accordingly. However, it is still a way of obtaining the right to keep accounts through competition based on hash operations, and its regulatory ability is weak. The fault tolerance of this consensus mechanism is the same as that of PoW. DPoS: The main difference from PoS is that nodes elect several agents, which are verified and recorded by the agents. Its compliance, performance, resource consumption and fault tolerance are similar to PoS. PBFT: It is a consensus mechanism that uses permissioned voting and majority rule to elect leaders for bookkeeping, but this consensus mechanism allows Byzantine Fault Tolerance. The consensus mechanism permits strong regulatory nodes to participate, with hierarchical permission capabilities, offering higher performance and lower energy consumption. In each round of bookkeeping, the entire network of nodes collectively elects a leader, allowing up to 33% of nodes to act maliciously, with a fault tolerance of 33%. PoA: It directly specifies which nodes have the right to keep accounts. Other nodes pass the algorithm. If the authorized node makes a block, the block is deemed valid. The node with the right to keep accounts needs to be authorized by the genesis node to have the right to keep accounts.

Chapter 4 MedBlock Protocol Application scenarios Everyones daily health data and medical-grade health data hold immense value for users themselves. The MedBlock Protocol network combines blockchain technology with artificial intelligence, enabling users to access continuous health and medical services through AI analysis of their data while ensuring privacy. Moreover, user data has significant research value, providing substantial support for the development of medical technology. Blockchain technology can selectively flag certain types of data as "anonymously tradable." The MedBlock Protocol network will provide these anonymized data to pharmaceutical companies and research institutions on a paid basis according to customer preferences. This process is realized through smart contracts, with the generated revenue being transferred into the customers wallet via MBP. Users can obtain a one-stop solution for health monitoring and management, medical service support, and ensure effective assistance for the development of medical technology through the MedBlock Protocol network. 4.1 Health services Health monitoring and management services Bobs wearable device continuously monitors various data points of his body, covering all activities from the physical to the brain. The biosensors analyze and compare the data collected by different devices, and can cross-reference the analysis results with medical literature records, which are then documented in Bobs Olive profile. MedBlock Protocol extracts various health data from Olive, and after monitoring and analysis, MedBlock Protocol finds that Bobs health condition is deteriorating, specifically manifested as weight gain, poor sleep quality, and high blood sugar levels. MedBlock Protocol believes that if this continues, Bobs risk of developing chronic diseases such as diabetes will gradually increase, and reports

this possibility to Bob. After realizing his health issues, Bob begins to actively adjust his lifestyle. Diet and exercise guidance services Jenny hopes to adjust her sub-health condition through a healthier diet and exercise, but she has no reasonable way to do so If you go to the gym and learn from a fitness coach, it could cost a lot of money. So, Jenny uploaded her body data and dietary habits to MedBlock Protocol. With Jennys consent, MedBlock Protocol also read other data from Jennys MedBlock Protocol, such as genetic data and sleep data. Through data analysis, MedBlock Protocol provided Jenny with a detailed meal plan and exercise program. This smart meal plan and fitness program can be dynamically adjusted based on Jennys progress, while continuously urging her to complete daily diet and exercise tasks, helping Jenny achieve the best results. Customized chronic disease management services Bill has recently been troubled by chronic hypertension caused by obesity. Over the past period, Bill has tried various blood pressure medications and weight loss methods. Unscientific approaches not only failed to control his weight but also led to increased blood pressure, severely impacting his health. MedBlock Protocol analyzed Bills physical condition and tailored a comprehensive blood pressure management plan for high BMI, including medication supervision, diet, exercise, and sleep schedules. They also adjusted Bills previously irregular lifestyle and eating habits, making adjustments based on his progress to improve his health status and provided long-term services to Bill.

4.2 Medical services Intelligent triage and guidance system William has been feeling unwell recently, but there are no obvious symptoms, so he consulted MedBlock Protocol. MedBlock Protocol analyzed Williams consultation information and his Olive profile, finding that all of Williams physical data were normal. After a thorough analysis, MedBlock Protocol discovered that William might have some issues with his mental state, showing signs of potential depression. Therefore, they recommended that William visit a professional psychologist for more detailed treatment. Upon visiting the psychologist, William was diagnosed with mild depression and quickly saw improvement after taking medication. Global medical services connection David suffered from a rare blood disease for which there were almost no doctors in his country with treatment experience. Through the MedBlock Protocol database, David found that a private hospital in the United States had three successful cases of this blood disease. David reached out to local doctors via MedBlock Protocol for details and procedures of past cases. Ultimately, David recognized the hospitals capabilities and decided to seek treatment abroad, resolving the currency exchange issue by paying MBP. Course of treatment and postoperative rehabilitation Havel is a cancer patient undergoing treatment that is vastly different from traditional cancer therapy. Apart from one surgery at a well-known oncology hospital in the area, his chemotherapy, physical therapy, and nutritional supplements are all administered at home. Havels family has become more involved in his recovery process, using MedBlock Protocol to better understand what is happening with him and actively offer support. If Havel encounters any issues

during his personalized care, he can receive voice-guided services for tumor rehabilitation through MedBlock Protocol at any time. Clinical participation in special diseases John has just been diagnosed with a rare form of cancer. Through MedBlock Protocol, he discovered that there is currently a targeted drug for his cancer recruiting clinical trial volunteers. After careful consideration, John decided to participate in the clinical trial of this drug. During the clinical trial, MedBlock Protocol helps John manage his diet, daily routines, and other aspects according to the trial requirements uploaded by the testing institution, while also monitoring and tracking data to provide better support for the clinical trial of the drug. In addition to offering a better solution for his illness, John can also earn a certain amount of MBP rewards. Gene testing and interpretation services After her mother was diagnosed with breast cancer, Mary became concerned about the risk of developing the disease herself. However, due to the nature of her job, she did not have the time to undergo genetic testing at a professional facility. She shared this concern with MedBlock Protocol, who used ALV to help Mary book a genetic testing and interpretation service. That evening, Mary received a saliva sampler. Following the instructions, she collected samples and sent them back to the testing center. Subsequently, Mary received her genetic test report, which indicated that she carried the same breast cancer gene as her mother and had a higher probability of developing ovarian diseases compared to the general population. During her annual health check-ups, MedBlock Protocol would remind Mary to focus on breast and ovarian health, such as mammography and ultrasound examinations, monitoring changes in her breast and ovarian conditions and recording them. If any potential abnormalities were detected during follow-up,

MedBlock Protocol would advise Mary to undergo further tests. 4.3 Drug research and development and drug traceability Pharmaceuticals and research and development MediResearch is an alliance formed between pharmaceutical companies, data management and analysis firms, and non-profit genetic engineering organizations. The current focus of this alliance is to guide new drug development based on large amounts of patient biomarkers and genomic data. Through standardized smart contracts in MedBlock Protocol, it is possible to efficiently obtain vast amounts of anonymized information. This information has effectively advanced the research progress of the alliance, leading to preliminary findings on when specific drugs should be administered to certain populations. Drug traceability-supply chain phase Carol had a high fever reaching 40 degrees, suffering greatly from the headache and muscle pain caused by the fever. After MedBlock Protocol detected Carols condition, it submitted the temperature data collected by the smart terminal and the allergy report previously uploaded to Olifes user profile to a nearby pharmacy. MedBlock Protocol then placed an order for suitable prescription medication for Carol through the supply chain, which was delivered to her home. When the medication arrived, MedBlock Protocol helped Carol verify its authenticity by comparing the full supply chain information on the blockchain. 4.4 Medical insurance and mutual aid

Medical insurance services Alice wants to purchase a health insurance policy for herself. Now, she no longer needs to prepare complicated additional documents; the insurance company can retrieve her Olife profile in a single authorized order for eligibility review and to determine the insurance terms, with payments and pricing made through derivative tokens. The process for insurance reimbursement will also be simplified. When Alice incurs medical expenses that meet the insurance criteria, a preset smart contract will automatically trigger, and the amount covered by the insurance compensation will be automatically transferred to Alices MBP electronic wallet. Medical mutual aid services Tony is a gout patient who initiated a gout mutual insurance project in the Gout Mutual Aid Group on MedBlock Protocol. Other users of the Gout Mutual Aid Group who wish to participate in the mutual insurance can entrust their insurance premiums, priced with derivative tokens, to a smart contract. All users who purchase insurance can check the coverage amount at any time, and the entire process from subscription to claims is transparent, open, and automated.

Chapter 5 Development Planning 5.1 Development roadmap Integrate the Internet of Things platform and release the MedBlock Protocol payment system In the first quarter of 2025, MedBlock Protocol project was launched and white paper was released The demo medical health management hardware equipment will be completed in the second quarter of 2025 In the third quarter of 2025, the mining ecology of health data will be completed Publish MedBlock Protocol public chain

5.2 Development steps 5.2.1 Initial planning  2024 Q2 Research on blockchain and related issues in medical applications  In Q3-Q4 of 2024, the project will be started and preliminary research will begin 5.2.2 Medium-term planning  In Q12025, the research will be completed and the white paper will be released  In 2025 Q2, we will complete the demo of medical health management hardware equipment  Completion of version DAPP demo by Q32025  In 2025 Q4, we will complete the construction of the health data mining ecosystem 5.2.3 Future planning Cooperate with community hospitals, nursing homes and health groups to provide health management and consultation for geriatric diseases and chronic diseases. Chapter 6 Team Introduction The birth of a great cause is inseparable from a great team. MedBlock Protocol has gathered the active participation of elite talents from various industries at the beginning of its establishment, which has laid a solid foundation for the grand development prospect of MedBlock Protocol.

Chapter 6 Team Introduction 6.1 Core team He has held many important positions in the government. In 2006, he served as Queenslands Health Minister; In 2005, he served as Minister of Natural Resources and Mines of Queensland; In 1998, he served as Minister for Industry in Queensland; In 1992, he served as a member of the Queensland Parliament (acting Premier); In 1984, he was a member of the Queensland Parliament; Henry Palaszczuk Hon Heinrich Henry Whiteley Position: Founder Main responsibilities: Responsible for the overall planning of MedBlock Protocol projects and major decisions of the foundation. Historical achievements: A famous Australian politician, he has great influence in both politics and business, and has been a politician in Queensland

Edward Moser (Edvard Moser) Position: MedBlock Protocol Scientific adviser. Main responsibilities: Responsible for genetic science research and application. Historical achievements: Nobel Prize in Physiology or Medicine winner; Norwegian psychologist, bio-neuroscientist; Norway He is the founding director of the Institute of Systems Neuroscience and the Center for Memory Biology at the University of Wisconsin-Kefalokos Institute of Science. In 2018, he was awarded the Royal Norwegian Order of St. Olaf; In 2014, he won the Nobel Prize in Physiology or Medicine; In 2013, she received the Louise Gross Horvitz Award from Columbia University; In 2012, he received the Perl-UNC Neuroscience Award; In 2011, he was elected a member of the European Academy of Sciences; George Smoot (George Fitzgerald Smoot III) Position: MedBlock Protocol Scientific adviser. Main responsibilities: Responsible for gene data analysis, computing and application technology. Historical achievements: Nobel Prize in Physics; recipient of the Einstein Medal; known as the "father of cosmic embryology"; Professor of physics at the University of California, Berkeley. In 2006, he shared the Nobel Prize in Physics and the Gruber Prize with John Matherin; In 2003, he received the Einstein Medal; In 2002, he was awarded the Medal of the French Academy of Francois; In 1994, he won the Golden Plate Award from the American Academy of Academic Achievement; In 1991, he was awarded the NASA Outstanding Scientific Achievement Award; David Crony (David Cronin) Position: MedBlock Protocol Medical expert consultant. Main responsibilities: Responsible for resource integration and strategic cooperation in the life and health industry.

Historical achievements: Bachelor of Medicine, recipient of the Australian Queensland Public Scholarship, Medical Scholarship, Australian Ear He has been awarded the Medal of the Society of Otolaryngology and Head and Neck Surgery, the Medal of Outstanding Expert Contribution, and has been engaged in medical research for more than 50 years He has a high reputation in the Australian medical community for many years. In 2019, he served as deputy director of QLM International Anti-aging Center in Australia; In 2008, he was appointed professor at the School of Health Sciences, Bond University; In 1998, he served as president of the board of directors of Pindara Private Hospital; In 1983, he was an expert doctor in the ENT department of the Public Hospital of Gold Coast University; In 1974, he was awarded the title of FRACGP Fellow of the Royal Australian Academy of Medicine; Michael Gordon (Michael Carlyle Gordon) Position: MedBlock Protocol Medical expert consultant. Main responsibilities: Responsible for the comprehensive management of GTA gene data storage and application in terms of ethics. Historical achievements: Australian famous medical expert, has won the National Outstanding Expert Contribution Award, engaged in medical research for more than 50 years, He enjoys a high reputation in the Australian medical community. In 2015, he was president of the Queensland Surgical Surgeons Committee and the Obstetricians and Gynaecologists Committee; In 1990, he served as the president of Yipusri Public Hospital; 1978 Expert adviser, St Andrews Hospital; In 1977, he was awarded the title of Fellow of the Royal College of Surgeons in the United Kingdom In 1975, he was awarded the title of Fellow of Royal Obstetrics and Gynaecology Society of Australia and New Zealand;

To ensure the smooth operation and interaction among all roles in the MedBlock Protocol ecosystem, MedBlock Protocol has introduced a token system. MBP is the native token of MedBlock Protocol, serving as the carrier of internal rights within MedBlock Protocol and also as the means of value circulation between MedBlock Protocol and fiat currencies, as well as other cryptocurrencies. Derivative tokens are the right carriers for various DAPPs on the chain, allowing DAPPs to design and issue derivative tokens through MBP. We have every reason to believe that under the inspiration of MedBlock Protocols core team, it will certainly promote the rapid spread and popularization of MedBlock Protocol globally, and generate tremendous momentum for building a broad consensus. At the same time, as MedBlock Protocols influence continues to grow, it will attract more high-quality resources from investment institutions, the life health industry, and the blockchain sector to join in, collectively advancing this great cause of MedBlock Protocol.

Chapter 7 Token Offering Plan 7.1 Total issuance Token name: MBP Total issuance: 200000000 IDO:30% Technology: 10% Operations: 30% Foundation: 15% Environmental mining: 15% Price: $0.99 7.2 Launch programme  The team reserves 20%;  Mining 80%.

7.3 Token acquisition path DAPP issues its own native tokens by deploying smart contracts. Users can use fiat currency to obtain MBP tokens in the corresponding DAPP, and can also obtain corresponding MBP token rewards by participating in the community construction at the DAPP level; 5. In subsequent application scenarios, the corresponding MBP is obtained through shared resources and content services; 6. Users can participate in official MedBlock Protocol activities and obtain corresponding MBP according to the activity rules.

Chapter 8 Disclaimer Please read this disclaimer carefully. If you have any questions about what you should do, you should consult your legal, financial, tax or other professional adviser. The information contained in this white paper may not be exhaustive and does not constitute any element of the contractual relationship. We make every effort to ensure that the materials in this white paper are accurate and up-to-date, such as product, service, technical architecture, token distribution, etc. Furthermore, any changes to material information made without notice do not constitute participation in the project. This white paper does not constitute any investment advice, investment intention or inducement to invest in the form of securities. This white paper does not constitute and is not understood as providing any buying or selling activity, or any invitation to buy or sell any form of securities, nor is it any form of contract or commitment. MedBlock Protocol The project team clearly indicates that the relevant intended users clearly understand the risks of the project. Once investors participate in the investment, they indicate that they understand and accept the risks of the project, and are willing to bear all the corresponding results or consequences for themselves. This white paper does not constitute any type of prospectus or offer document and is not intended to constitute a securities offer or solicitation of investment in any jurisdiction

Appendix II References 1. 《POLKADOT: VISION FOR A HETEROGENEOUS MULTI-CHAIN FRAMEWORK》 (DRAFT 1) DR. GAVIN WOOD FOUNDER, ETHEREUM & PARITY 2. 《Cosmos：A Network of Distributed Ledgers》Jae Kwon , Ethan Buchman 3. 《The Genomics Bottleneck》 The Hutch Report 4. 《Filecoin: A Decentralized Storage Network》Protocol Labs 5. 《YottaChain: RedefineBlockchainStorage》YottaChain Foundation 6. 《Bitcoin: A peer-to-peer electronic cash system》Nakamoto 7. 《A Smart Contract Reefereed Date Retrieval Protocol With A Provably Low Collateral Requirement》JamesM.Shook,ScottSimon,PeterMe 8. 《General Data Protection Regulation, GDPR》European Commission