cats with diabetes - advice?

So I just found out Tico has diabetes. My vet has recommended:

a new diet of all wet prescription food

an insulin injection every twelve hours

monitoring glucose levels, either via frequent vet trips or via home monitoring, which involves pricking his ear for blood often IIUC

This is going to be extremely difficult for several reasons, but mostly because I'm usually gone a couple times a week for 18-36 hours. I have until now just left out a bunch of dry food for all three of them, and they've been okay without me there.

I can solve the problem of "I have three cats with different diets now who will want to eat each other's food" -- there are now RFID feeders that I can key to their microchips (so the feeder only opens when the right cat approaches -- which will apparently scare the hell out of them at first, but they'll hopefully adapt). But the injections + wet food every twelve hours is going to be HARD.

I asked the vet, "My parents had a diabetic cat who only got injections once a day -- is it possible to adjust the injection schedule to that? Or how bad is it if he misses an insulin dose a couple times a week, or if he eats dry food on those days?" All the vet would say is, "That's not recommended." But, like ... would it mean a minor decrease in his quality of life? Or would it make him get much sicker, or be noticeably uncomfortable? They wouldn't say anything. I know it varies a lot by pet, but does anyone have relevant experience here?

Also, does an ear prick blood draw bother a cat? Am I going to be able to do that at home? idk. [Edit: but my cats are nearly impossible to pick up or capture, so going to the vet regularly sounds bad.] I know the insulin injection in the scruff isn't noticed by most cats, at least.

We're supposed to take him back in on Saturday for more tests, because he's got other issues, too. Poor kitty.

India Blood Bag Market size by value at USD 51.82 billion in 2023. During the forecast period between 2024 and 2030, BlueWeave expects India Blood Bag Market size to expand at a CAGR of 5.23% reaching a value of USD 72.93 billion by 2030. The Blood Bag Market in India is propelled by the rising chronic disease rates, an uptick in surgical procedures, and government initiatives to bolster healthcare infrastructure are key drivers. Innovations in materials science, like advanced polymers and biocompatible materials, enhance blood bag durability and flexibility, ensuring optimal blood preservation. Improved designs, incorporating features such as integrated filters and ergonomic handles, boost functionality. Technological advancements in storage, including automated temperature monitoring and cryopreservation techniques, are expanding the horizons of transfusion therapies. Moreover, automated barcode and RFID systems streamline traceability, safety, and inventory management, ensuring regulatory compliance and product integrity.

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Medical Transport Boxes: Ensuring Safe and Efficient Healthcare Logistics

The global medical transport box market is experiencing significant growth, driven by the increasing need for secure and temperature-controlled transport solutions in the healthcare sector. Valued at USD 603.75 million in 2022, the market is projected to reach USD 1061.81 million by 2030, with a compound annual growth rate (CAGR) of 7.30% during the forecast period from 2023 to 2030. This growth highlights the crucial role that medical transport boxes play in ensuring the integrity of medical supplies throughout the supply chain.

Why Medical Transport Boxes?

Medical transport boxes are essential for safely transporting temperature-sensitive medical items such as vaccines, blood samples, organs, and pharmaceuticals. These boxes are designed to maintain specific temperature ranges and protect against contamination, ensuring that medical products reach their destinations in optimal condition. As the healthcare industry becomes more globalized and interconnected, the demand for reliable and compliant transport solutions is on the rise.

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Technological advancements are transforming the medical transport box market, enhancing the efficiency and reliability of these critical tools. Innovations such as advanced insulation materials, real-time temperature monitoring, and GPS tracking are improving performance and providing better control over the transportation process.

Market Dynamics and Growth Drivers

Several factors are fueling the growth of the global medical transport box market:

Rising Demand for Temperature-Controlled Solutions: The need for maintaining strict temperature control during the transport of medical products, including vaccines and biologics, is a major driver of market growth. Medical transport boxes equipped with sophisticated thermal insulation and cooling technologies are essential for preserving the efficacy of these products.

Expanding Global Healthcare Infrastructure: The growth of healthcare infrastructure worldwide, particularly in emerging markets, is increasing the demand for reliable medical transport solutions. Medical transport boxes play a vital role in ensuring that medical supplies are delivered safely to even the most remote locations.

Regulatory Compliance and Quality Assurance: Stringent regulations governing the transportation of medical products require adherence to specific standards for temperature control, security, and durability. Compliance with these regulations is driving the adoption of high-quality medical transport boxes.

Technological Innovations: Advances in materials science and digital technology are enhancing the capabilities of medical transport boxes. Features such as real-time tracking, tamper-evident seals, and RFID tagging are becoming standard, providing greater visibility and control over the supply chain.

Challenges and Opportunities

The market faces challenges such as the high cost of advanced transport solutions and logistical complexities associated with maintaining temperature control during long-distance transport. Additionally, fluctuating raw material prices can impact manufacturing costs.

However, there are significant opportunities for growth. The demand for cost-effective yet reliable transport solutions is driving innovation in the market. Expanding into emerging markets and exploring new applications for medical transport boxes can provide additional growth avenues.

Regional Analysis

North America: The North American market is characterized by a well-established healthcare sector with a focus on innovation and regulatory compliance. The U.S. and Canada are significant contributors to the market, driven by ongoing advancements in medical transport solutions and infrastructure development.

Europe: Europe’s market benefits from strong regulatory frameworks and a focus on high-quality healthcare logistics. Countries such as Germany, France, and the U.K. are key players, emphasizing the need for reliable and compliant transport solutions.

Asia-Pacific: The Asia-Pacific region is experiencing rapid growth due to increased urbanization and healthcare infrastructure development. Emerging markets like China and India are driving demand for medical transport boxes, supported by rising healthcare needs and logistical challenges.

Latin America and Middle East & Africa: These regions are showing gradual growth, influenced by expanding healthcare infrastructure and increased investments in medical logistics. The need for reliable transport solutions in these regions is contributing to market development.

Report Overview : https://www.infiniumglobalresearch.com/market-reports/global-medical-transport-box-market

Competitive Landscape

The medical transport box market is competitive, with a range of players offering diverse solutions. Key players include:

Thermo Fisher Scientific: A leading provider of temperature-controlled transport solutions with a focus on innovation and compliance.

Pelican BioThermal: Known for its high-performance transport solutions and extensive range of medical transport boxes.

VWR International: Offers a wide variety of medical transport boxes and solutions, catering to different healthcare needs.

Cryoport: Specializes in temperature-controlled logistics and provides advanced solutions for the medical transport industry.

Emerging players and local manufacturers also contribute to market dynamics, providing innovative and cost-effective solutions.

Conclusion

The global medical transport box market is poised for substantial growth, driven by the increasing needs of the healthcare industry and advancements in medical logistics. With revenue expected to reach USD 1061.81 million by 2030, the market offers ample opportunities for innovation and investment. As the healthcare sector continues to evolve, medical transport boxes will remain a critical component in ensuring the safety and efficacy of medical supply chains.

The Role of Technology in Modern Blood Bank Management

In the realm of Blood Bank Management, technology plays a pivotal role in enhancing efficiency, accuracy, and patient safety. Let's explore how various technological advancements are revolutionizing blood bank operations:

Inventory Optimization: Effective inventory optimization is essential for ensuring that blood banks have an adequate supply of blood products to meet patient needs while minimizing wastage. Advanced inventory management systems utilize real-time data and predictive analytics to forecast demand, track inventory levels, and automate replenishment processes, ensuring optimal stock levels at all times.

Donor Recruitment: Leveraging technology for donor recruitment has transformed the process of blood collection. Online donor portals, mobile applications, and social media campaigns enable blood banks to reach a broader donor pool, streamline appointment scheduling, and provide convenient donation options. By harnessing technology, blood banks can engage donors more effectively and maintain a consistent blood supply.

Blood Component Tracking: Accurate blood component tracking is critical for ensuring the traceability and safety of blood products throughout the supply chain. Barcode and RFID (Radio-Frequency Identification) technology enable blood banks to track each blood component from collection to transfusion, ensuring proper handling, storage, and distribution. This level of traceability enhances blood product quality and patient safety.

Expiry Monitoring: Technology-enabled expiry monitoring systems help blood banks prevent the wastage of blood products by tracking expiration dates and facilitating timely usage or disposal of nearing-expiry units. Automated alerts and notifications ensure that blood bank staff are promptly notified of expiring products, allowing for proactive management and optimization of inventory.

Automated Matching: Automated matching algorithms utilize advanced computational techniques to match donor blood with recipient blood, ensuring compatibility and reducing the risk of adverse transfusion reactions. These algorithms analyze donor and recipient characteristics, such as blood type and antigen compatibility, to identify suitable matches quickly and accurately, enhancing patient safety during transfusions.

In conclusion, technology plays a transformative role in modern Blood Bank Management, revolutionizing inventory optimization, donor recruitment, blood component tracking, expiry monitoring, and automated matching processes. By embracing technological innovations, blood banks can enhance operational efficiency, ensure blood product quality, and ultimately improve patient outcomes.

Precision Medicine and IoT: Advancements in Personalized Healthcare - Technology Org

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Precision Medicine and IoT: Advancements in Personalized Healthcare - Technology Org

Precision medicine and technology together have the potential to completely transform healthcare. Using precision medicine techniques, patterns are found in patients with uncommon treatment responses or distinct medical needs. Artificial intelligence and other cutting-edge technologies allow the system to think and learn, develop insights through complex computing and inference, and enhance clinician decision-making.

When combined with smart gadgets like Internet of Things (IoT) medical technology, this enables medical practitioners to individually customize a patient’s course of care. According to recent research, translating this technology integration into ongoing research will help tackle precision medicine’s most challenging problems, particularly those where unique medical issues, when paired with patient symptoms, clinical history, and lifestyle data, will enable personalized diagnosis and prognostication.

Internet of Things – artistic impression. Image credit: geralt via Pixabay, free license

IoT in Personalized Care

Advancements in medical technology have led to astounding developments in patient care. As little as two decades ago, patient treatment involved the sick person traveling to a physician’s office, undergoing rounds of tests and treatment at those locations, staying overnight in clinics to conduct rounds of lengthy testing, and a variety of other activities that were time-consuming and difficult for both the patient and the doctor. Now, thanks to IoT technology in healthcare, patients can undergo some testing, such as heart monitoring and sleep monitoring, at home with devices that connect to the Internet and send data in real-time to their physicians. Some ways in which the Internet of Things helps to personalize healthcare include:

Reducing waiting time by using telehealth and remote services connecting doctors and patients at their locations rather than require time to travel and wait in a doctor’s office.

At-home monitoring devices are now used for diagnosing disorders such as sleep apnea.

Using technology such as Near Field Communication (NFC) and Radio Frequency

Identification (RFID) technology to allow medical monitoring devices to interact with smartphones and mobile devices, sending alerts to the patient, such as a low blood sugar alert.

Cloud computing allows for apps such as MyChart, which allow patients to communicate via message with their doctors, view and share test results and medication lists with various providers.

Making use of IoT in healthcare through smart devices such as the Apple Watch for fall detection, medical alert monitoring, medication reminders, summoning emergency services, and heart rhythm monitoring.

IoT in Precision Medicine

Precision medicine, as defined by the Precision Medicine Initiative, is “an emerging approach for disease treatment and prevention that takes into account individual variability in genes, environment, and lifestyle for each person.” With this method, medical professionals and researchers will be able to more precisely forecast which preventative and treatment plans will be most effective for a certain disease in which populations in contrast to a one-size-fits-all approach ignores individual differences. Although it is a new term, it is not a new concept. For example, considering one of several personalized medicine examples, once medical providers realized that humans had several different blood types, treatment for blood transfusions was catered to the type of care a person with a particular blood type needed. Consider the following precision medicine examples:

Integrating artificial intelligence (A.I.) with machine learning models to aid in patient diagnosis, utilizing data from medical smart devices as it is collected.

Expand telemedicine, which enables patients to access timely healthcare remotely.

Wearable technology, such as smart watches with integrated health monitoring features that monitor chronic conditions and scan for any developing conditions, allows for early detection.

Improved patient care in medical facilities through IoT devices in hospitals and clinics that allow for easier and faster check-in, and assist in ongoing care.

Genetic Testing, Treatment and IoT

Genetic treatment, or cell-based therapy, has a wide variety of applications when paired with IoT-enabled hardware. With data collected from connected technological devices, physicians can monitor certain types of cancer developments, implement treatment through personalized application devices such as pumps or implants, or even enhance or suppress various bodily functions.

Genetic testing now allows medical providers to get a better idea of who might be most likely to develop certain chronic conditions, such as diabetes and high blood pressure, which then allows for precise and targeted monitoring of the individual through smart medical devices.

Remote Patient Monitoring

Medical monitoring is perhaps one of the most useful and powerful applications of IoT solutions for healthcare. As medical devices become smaller and more easily wearable, individuals can then make use of devices such as smartwatches to monitor their ongoing health and make note of any changes, many of which are often subtle and unnoticed in daily life, to determine worrisome patterns over time. Apps such as Apple’s Health app show trends over time collected by devices such as the Apple Watch, which continuously monitors heart rate, breathing, time spent sleeping, and a whole host of other useful features.

These insights give doctors much-needed information to tailor their treatment to the patient’s individual condition. In some cases, devices like the Apple Watch can take a single lead EKG reading to check for atrial fibrillation, which can be exported to a PDF and uploaded via MyChart to a cardiologist, who can then decide if a patient needs further testing and monitoring from dedicated medical devices.

To Recap

As we can see, the IoT has great potential in precision healthcare, as the data collected from these devices allows physicians to offer personalized healthcare solutions and greater flexibility for personalization in healthcare. As technology becomes more powerful, perhaps even utilizing A.I. in diagnostics, we can easily see a future in which, like in the television series Star Trek: Voyager, an A.I. holographic doctor who diagnoses and treats conditions (under the direction of a human doctor) gives patients the opportunity for more frequent and personalized medical care at a moment’s notice.

The Wristband Revolution: From Fashion Statements to Functional Gadgets

Wristbands, those little loops around the wrist, have changed a lot over time. What started as adornments or markers of commitment to a cause has grown into a vast category of accessories that merge fashion, technology, and practicality in ways imagined a few decades ago.

Initially, wristbands were decorative, made of leather, cotton, and subsequently plastics and silicones. They were fashion statements that expressed personal style or allegiance. Popular social cause bands used colors and emblems to raise awareness for environmental protection and human rights. These inexpensive items allowed people to publicly express their private beliefs.

Wristbands evolved with technology. Wearable technology made wristbands active participants in people's lives. Fitness monitors with heart rate, step, and calorie sensors became popular. Wearable wristbands connected to cellphones and computers provide real-time data on physical activity and health indices. The seamless integration of these gadgets into daily life made technology more personal and accessible.

RFID chips incorporated in fabric or silicone wristbands boosted their use at festivals. This high-tech wristband changed event administration by securely managing admission, payments, and attendee social interactions. No more searching for tickets or cash—a wristband tap on a scanner allowed for quick access, purchase, and interaction, improving the experience for organizers and participants.

In health and wellbeing, medical ID wristbands are crucial. These silicone bands save medical information including allergies, ailments, and emergency contacts. In cases of unable to communicate, these wristbands can speak for the wearer and provide prompt care. QR tags and NFC technologies have been added to these bracelets to give doctors a complete medical history with a scan.

Never one to be left behind, the fashion industry has embraced the wristband, using luxurious materials and sophisticated aesthetics. Luxury brands and boutique designers have reinterpreted the wristband utilizing leather, precious metals, and jewels to create jewelry-like accessories. These designer bracelets show that even basic items can be luxurious and status symbols for a market that values exclusivity and style.

Wristbands are also designed and made with environmental and ethical considerations. The rise of recycled plastics, organic cotton, and biodegradable materials shows an increasing awareness of consumer goods' environmental impact. Fair trade and ethically sourced products are selling advantages for consumers who want to make responsible purchases.

Only imagination and technology seem to limit bracelets' future. Materials science advances could provide wristbands that change color or design with mood or environment. Advances in biometric technology may allow wristbands to track more health indicators, such as blood pressure and glucose, for greater wellness insights. Augmented reality and holographic displays could make wristbands useful digital communication tools.

Wristbands have evolved from simple strips. They adapt to society's shifting needs at the nexus of fashion, technology, and personal expression. Wristbands have been adaptable and enduring accessories in human culture, functioning as a statement of support, a tool for health and fitness, a badge of access, or a piece of wearable art.

NFC Chips as a Solution: Market Players Open for R&D Investments

From information transfer to contactless payments to security, NFC chips have emerged as an ideal authentication and data protection solution. The near field communication chips market has witnessed significant expansion over the years, owing to innovative applications of NFC technology across industries.

Considering the rising application of NFC chips, numerous companies are embedding them in consumer electronics, especially smartphones. For instance, Google Nexus and HTC mobile include NFC chips that ensure data security with the help of encryption. Additionally, the COVID-19 outbreak led to a surge in smartphone penetration, resulting in high volume sales of around 2.2 billion NFC-enabled smartphones in 2020. Estimates indicate that NFC tags are estimated to prove beneficial in various applications, including TV, Wi-Fi router, and fridge, given the rising trend of contactless operations.

Triton Market Research estimates that the global near field communication (NFC) chips market will advance with a CAGR of 12.99%, reaping revenue worth $7.47 billion by 2028.

Market Expansion by Application

Application plays a major role in influencing buyers’ behavioral patterns. Over the years, the use of NFC chips has evolved, ranging from contactless payments to advanced logistics to consumer engagement. In this regard, the end-users, especially automotive, consumer electronics, and retail sectors, compare various chips as per their application range and cost. This has led companies to invest heavily in R&D to expand their footings. For instance, Broadcom Corporation launched an NFC chip into the automotive product line to effectively connect mobile devices to vehicle infotainment systems.

Major application areas that widen the scope of the NFC chips market:

Smartphones capture a significant share in the near field communication chips market. Technological advancements and R&D activities in NFC chip-enabled devices have contributed to the smartphone segment growth. The NFC chips are used to ensure secure and short-distance communication. As a result, several prominent players are expanding their product line with NFC chips. For instance, NXP Semiconductors launched a single-die chipset that features NFC technology for smartphones as well as IoT devices, tablets, and laptops.

Another company, Thinfilm Electronics ASA, raised over $110 million to boost NFC technology in consumer electronics, such as smartphones and other devices. This indicates the consumer electronics sector to secure a major share in the vertical segment.

Near field communication chips have emerged as a vital addition to medical devices and equipment, owing to their ability to swiftly and efficiently transfer health data. The market scope has grown with NFC chips embedded in weight scales, blood pressure monitors, and glucose meters. Moreover, the NFC tags’ implementation as electronic health records to store patients’ medical history, prescriptions, and real-time data has created a profitable market for NFC chips in the medical vertical.

The Automated Assemble Corporation, for instance, launched technologically-advanced NFC tags to store crucial patient data, helping medical staff to update treatment records regularly while creating automated time stamps for patients.

While near field technology has secured a higher share in the consumer electronics and medical segment, its adoption in logistics and aviation is expected to widen the market’s scope over the forecast period. In this regard, NFC tags and RFID chips are integrated into goods to prevent thefts during transportation, identification, and tracking. The smart ticketing application has also driven NFC chips’ adoption rate for seamless transportation. For example, Go North East invested approximately $2.28 million to influence NFC chips adoption for contactless ticketing services.

Regional Market Analysis | Growth Position

China and India are estimated to emerge as the fastest evolving countries in the Asia-Pacific near field communication chips market. This robust growth is on account of rising government programs for digital transactions. As per the World Economic Forum, the Chinese government launched the Green Finance Project to promote cashless technologies like NFC technology. The Indian government, on the other hand, introduced PSUs that offer a 0.75% discount on fuel sale prices over digital payments. Such incentives have increased the NFC chips adoption rate in these nations in the wake of the contactless payment trend.

To further promote cashless transactions in the retail segment, public sector banks offer POS terminals to attract small merchants to the digital payment ecosystem. As a result, approximately 6.5 lakh machines have been issued to traders recently, contributing heavily to the Indian NFC chips market’s growth.

Within North America, the conjoint efforts of private organizations to promote cashless transactions, in addition to soaring smartphone sales, have created a beneficial market for NFC chips manufacturers. Moreover, the penetration of NFC-enabled mobile payment applications such as Amazon, Visa Paywave, and Paypal has propelled the near field communication chips market’s progression across the US and Canada. Our estimates indicate that the North American near field communication chips market to witness a CAGR of 13.18% during the forecast period 2022-2028.

Future Projections

NFC chips have emerged as a new archetype in the wireless communication technology segment, providing versatility in terms of security and data transfer. This has increased R&D activities across various start-ups aiming to expand footings in the market. These investments are expected to widen NFC technology’s scope for real-time reservation tracking and banking updates. As per OBRC estimates, around 100 start-ups have established operations in the field of near field communication, with many expanding research capabilities. Hence, observing a high number of start-ups indicates that the global NFC chips market will enlarge over the forecast period.

Frequently Ask Questions:

Q 1) What are the uses of NFC chips?

A: From information transfer to contactless payments to security, NFC chips have emerged as an ideal solution for authentication and data protection. NFC chips are widely used in contactless payment systems, allowing mobile and card payments.

Q 2) Which companies manufacture NFC chips?

A: Samsung Semiconductor Inc, Broadcom Corporation, Marvell Technology Group Ltd, EM Microelectronic Marin SA, Inside Secure SA, Mediatek Inc, Murata Manufacturing Co Ltd, NXP Semiconductors NV, MStar Semiconductor Inc, Stmicroelectronics NV, Qualcomm Inc, Renesas Electronics Corporation, Sony Corporation, Texas Instruments Inc, and Toshiba Corporation are leading companies manufacturing NFC chips.

*HIGH-TECH BEAMED BREAST CANCER ASSAULTS*

Karen Albreight remains a perfect example of, reportedly a whistleblower, to have been given not only breast cancer by Directed Energy Weapon (DEW) focused attacks but also a brain tumor. In fact as I create this post monitored, the focused breast assault continues.

Frankly I have no doubt that this major, again, major, slow-kill effort set up around me using neighboring locations, strategically for beamed weapon assaults inside my home, without a doubt is attempting to create synthetic laser beamed breast cancer or a brain tumor by cooking the area of my head that supplies blood to the brain which could also create a aneurysm.  

Today as well as the other day, I woke to now a third powerful laser beamed energy weapon attack to my left breast side. The drone they are using is clearly seen in the night's sky over my house at night.  

When this program sets up around a target, as the Black LAPD killer cops, whom they hired specifically, and twisted death ray military personnel move into your community involved in this program, you have become a priority for covert strategic deterioration of your health by any means necessary and deemed undesirable. To show how diabolical this program is, they had a distant relative call me out of the blue, it appears, while the FBI listened in the background, just to report she had breast cancer. Her side of the family has the BrCa gene and not mine. However, immediately after we got off the phone, immediately, believe it or not, the beamed assaults to my breast began to escalate.  

I have had mammograms each year for 15 years and there has never been any issues including the last in 2022. 

Who is Katherine Albrecht?

"Katherine Albrecht is a consumer privacy advocate and spokesperson against radio-frequency identification (RFID). Albrecht devised the term “spy chips“ to describe RFID tags such as those embedded in passport cards and certain enhanced United States driver’s licenses. Katherine Albrecht holds a Doctor of Education degree from Harvard University. She is a resident of Nashua, New Hampshire."

Associated Links:

Stategic Slow-Kill Link:

*HIGH-TECH BEAMED BREAST CANCER ASSAULTS*

Katherine Albrecht remains a perfect example of, reportedly a whistleblower, to have been given not only breast cancer by Directed Energy Weapon (DEW) focused attacks but also a brain tumor. In fact as I create this post monitored, the focused breast assault continues.

Frankly I have no doubt that this major, again, major, slow-kill effort set up around me using neighboring locations, strategically for beamed weapon assaults inside my home, without a doubt is attempting to create synthetic laser beamed breast cancer or a brain tumor by cooking the area of my head that supplies blood to the brain which could also create a aneurysm.  

Today as well as the other day, I woke to now a third powerful laser beamed energy weapon attack to my left breast side. The drone they are using is clearly seen in the night's sky over my house at night.  

When this program sets up around a target, as the Black LAPD killer cops, whom they hired specifically, and twisted death ray military personnel move into your community involved in this program, you have become a priority for covert strategic deterioration of your health by any means necessary and deemed undesirable. To show how diabolical this program is, they had a distant relative call me out of the blue, it appears, while the FBI listened in the background, just to report she had breast cancer. Her side of the family has the BrCa gene and not mine. However, immediately after we got off the phone, immediately, believe it or not, the beamed assaults to my breast began to escalate.  

I have had mammograms each year for 15 years and there has never been any issues including the last in 2022. 

Who is Katherine Albrecht?

"Katherine Albrecht is a consumer privacy advocate and spokesperson against radio-frequency identification (RFID). Albrecht devised the term “spy chips“ to describe RFID tags such as those embedded in passport cards and certain enhanced United States driver’s licenses. Katherine Albrecht holds a Doctor of Education degree from Harvard University. She is a resident of Nashua, New Hampshire."

Associated Links:

Stategic Slow-Kill Link: https://youarenotmybigbrother.blog/2017/02/17/beamed-high-tech-synthetic-alzheimers-dementia-brains-aneurysms-and-strokes/

This program has had decades of practice in creating beamed heart attacks, Parkinson's, hip and knee replacements, breast and brain cancers, brain aneurysms, and more!  

The fact is after a certain age for women, who have never had any issues, again after 15 years, revealed through healthy breast mammograms each year, mammograms are no longer needed because of zero risk.

Recently after I turned down the Black goon cop's invitation to get involved with one of them, and they will live me alone, saying "I would rather be dead" in this JOINT operation, he said, "That can be arranged!"

A DIGITAL REVOLUTION IN PATHOLOGY

Laboratory medicine is continuously evolving to provide the much needed support for disease monitoring, treatment decisions and patient safety. With a rise in the adoption of machine learning and artificial intelligence to improve turnover and optimise efficiency, pathology laboratories are transforming into predictive rather than reactive environments.

Diagnostics is the critical first step in the healthcare delivery chain, as 70 per cent of the treatment decisions are based on lab results. The market for diagnostics devices is growing steadily to meet the increasing demand from hospitals and laboratories. The onus is thus on the manufacturer to provide a holistic solution that integrates automation with analytics, training, updates, and troubleshooting. Further, the use of QR codes and RFID chips enables automated tracking of samples and laboratory materials such as reagents, chemicals and equipment.

The role of AI and ML

Today, digitalisation, automation, and laboratory information software (LIS) have found a place in clinical laboratories. However, many lab processes continue to be performed manually or are partially digitised. Efforts are also being taken to improve the pre-analytic, analytic, and postanalytic processes of the clinical laboratories with the AI-support.

The COVID-19 outbreak accelerated the adoption of digital technologies in laboratories. According to a recently published report, several examples of applications of Artificial Intelligence (AI) to COVID-19 are already reported such as AI-enabled outbreak tracking apps, chatbots for diagnostics, AI-powered analysis of scientific publications and triage using natural language processing (NLP) for screening potential patients and prognosis prediction tools, and using radiology CT scans to manage system capacities, among others.

Also available on record are multiple examples of the role played by AI in the management of non-communicable chronic diseases such as cancer and cardiovascular disorders. AI tools aid in augmenting the accuracy of clinical decision and improving patient care.

Studies reveal that AI-supported systems can predict patient waiting time in the phlebotomy unit and organise the entire blood collection process or the autoverification of test results using a Machine Learning (ML) approach. ML can also be used to predict out-ofcontrol events in internal quality control studies, detecting instrument failures before even they occur, or determining compatibility between analysers in central laboratories where several instruments running the same parameters are tested.

Automation of analysers

It is very interesting that the basic manual laboratory techniques and procedures have generally been adopted in principle to automated, or mechanised, fashion in automated analysers, while a wide variety of configurations can be observed in modern instrumentation in clinical laboratory. Step-by-step innovations created these ultimate configurations.

There are several approaches to automated instrumentation historically. For instance, multiple samples are tested in a series in batch analysers. In contrast, in sequential analysers, the samples are tested sequentially, and the results are reported at that order. Continuousflow analysis means a form of sequential analysis with a continuous stream. In random-access discrete analysers, the most common configuration, analyses are performed sequentially on a set of specimens, and each sample can be analysed for a different test selection. In this type of analysis, an interruption can occur in routine working for spanning a stat sample in-between, permitting measurement of a number of and a variety of analytes in each specimen. Discrete term in this type of analysers means that each test of a patient (or a sample) is analysed in a distinct chamber (in a well, cuvette, reaction vessel)

The use of automated analysers has many advantages including reduction of workload, less time consumption per sample analysis, more number of tests done in less time, use of minute amount of sample, decreased chances of human errors, and high accuracy and reproducibility.

Further, Total Laboratory Automation (TLA) systems use conveyor belts to connect pre-analytical specimen processing and other functions directly to an analyser. Such systems also include functions such as post-analytical storage or sorting of specimens or aliquots to be transported to low-volume testing areas—or to be sent to reference laboratories.

At Transasia-Erba Group, we are looking forward to launching exciting new products by 2023. Our R&D labs in France, UK, USA, Austria and India will launch over 10 state-of-the-art analysers in CLIA, molecular, high-end haematology, AI and LIS. Also in the offing is a TLA solution aimed at midand large size laboratories. All these will make Transasia-Erba among the top-five companies globally to have ‘Total solutions in Laboratory Diagnostics.

Digital data management

Modern-day cutting edge smart technologies are giving a much-needed renovation to laboratories and making them ‘smart’. A smart laboratory is nothing but an amalgam of different hardware tools and software that helps in data management, which is one of its integral parts. And when it comes to data management, one cannot ignore the concept of digital data management.

The concept of digital data management generally revolves around utilising tools to store, document, and share, analyse and manage the experimental data. Among all the other software available, Laboratory Information Management System (LIMS) is extremely helpful. LIMS is a software solution that helps in addressing data management, regulatory challenges, and automation. This software is extremely useful in handling laboratory samples and the data. As a result, it helps maintain tests, workflows and reporting techniques that assist in standardising operations.

The most significant part of the LIMS is to enhance the operational efficiency of a lab by streamlining and automating workflows. Also, it eliminates the purpose of manually maintaining information and complying with regulations. An efficient LIMS will easily be able to keep records and report them. As a result, it eliminates the possibility of any human errors.

Benefits of using LIMS

The key advantage of using LIMS is that it provides sample management. It means that with the help of LIMS, it is possible to manage accurate and detailed records of every sample and securely store them. As a result, the data is not lost while it moves from one laboratory to another.

Secondly, the inventory management functionality of LIMS makes it possible to manage reagents and stock supplies. In addition, it also helps in generating automatic recorder alerts in time of depletion of the stock.

Test Management and reporting are the other two benefits of using the Laboratory Information Management System. It is possible to achieve standardised testing structures with the help of LIMS that too with the bonus of providing accurate and complete testing process control.

The Internet of Things

With an increasing focus on offering value-added services, manufacturers are adopting rapidly evolving technologies, such as the Internet of Things (IoT), to meet the huge demand for fully automated products and services.

IoT applications are being used across all industries and healthcare is no exception. In fact, IoT has brought in a lot of ‘convenience’ to the healthcare ecosystem, becoming especially useful for medical device providers. While it offers a host of solutions, it is left to the companies to leverage the potential of IoT to the fullest.

Predictive maintenance

For laboratories, one of the biggest concerns is downtime. Planning for upgrading via cloud-based lab management systems and sophisticated software is a good way to future proof products and reduce the cost of maintaining the instrument. The days of preventive maintenance are long forgotten, now is the time for predictive maintenance. Devices with IoT capability can sense when components are exhibiting faults or when they near their expected end of life and communicate this back to technical support and initiate actions to resolve them – from ordering replacement parts to requesting a completely new device.

Read More: https://www.europeanhhm.com/information-technology/a-digital-revolution-in-pathology

The Healthcare Asset Management Market: Tracking and Securing Assets to Improve Patient Outcomes

The healthcare industry is rapidly adopting asset management solutions to better track and secure assets across hospitals and pharmaceutical supply chains. According to a new report by MarketsandMarkets, the global healthcare asset management market is projected to reach $35.19 billion by 2023.

Asset management involves tracking medical equipment, pharmaceuticals, and other healthcare assets to optimize workflows, prevent losses, and improve patient safety. Radiofrequency identification (RFID) and real-time location systems (RTLS) are the main technologies driving growth in this market.

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RFID uses wireless tags and readers to identify and track assets, while RTLS utilizes badges, tags, and sensors to provide real-time visibility into asset locations. RFID hardware like tags, readers, and antennas account for the largest share of the healthcare asset management market currently. But RTLS solutions are expected to see the highest growth rate going forward due to their superior accuracy in confined hospital environments.

Managing Hospital Assets

Within healthcare facilities, asset management solutions have a wide range of applications to help hospitals enhance their operations. Asset tracking allows hospitals to locate wheelchairs, beds, IV pumps, and other mobile equipment faster so nurses spend less time searching and more time delivering patient care. Hospitals are using RFID and RTLS to gain real-time visibility into medical device utilization rates and accordingly optimize asset allocation.

Asset management also facilitates temperature monitoring of medications, blood products, specimens and donor organs to ensure proper storage conditions are maintained. Hand hygiene compliance is another important application, where automatic monitoring boosts adherence to hand washing guidelines and reduces the risk of hospital-acquired infections. Staff and patient workflows can also be streamlined by mapping movements and interactions between personnel, patients and assets.

The hospital asset management segment will account for the largest share of the healthcare asset management market. The main factor driving adoption is the need to improve asset utilization, staff productivity and patient outcomes through better asset visibility and control. This segment includes equipment tracking, patient management, temperature monitoring, hand hygiene compliance, and staff management solutions.

Securing Pharmaceutical Assets

In pharmaceuticals, asset management combats counterfeiting and enables end-to-end visibility across the supply chain. Tagging and tracking individual drug packages limits diversion and ensures authenticity from production to the end consumer. The pharmaceutical asset management segment is growing rapidly as companies implement RFID and RTLS to prevent fake, expired or recalled drugs from entering supply chains. Asset management also helps pharmaceutical companies adhere to regulatory compliance requirements regarding drug storage, transit and handling conditions.

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Key Market Trends and Developments

The healthcare asset management market is currently led by North America, followed by Europe. Widespread adoption of advanced medical technologies, emphasis on improving hospital workflows, and investments in digitizing supply chains is driving North American market growth.

But Asia is poised to see the fastest growth over the coming years. Rising medical tourism, healthcare infrastructure modernization and increased spending on asset management solutions will spur demand across Asian countries.

The increasing application areas for asset management within healthcare reflects the significant potential of this market. Though the costs associated with RTLS and RFID solutions may restrain smaller facilities, the benefits of greater asset oversight are too compelling for hospitals and pharmaceutical companies to ignore. Asset management adoption will continue expanding as healthcare providers and supply chain partners realize the value of securing and optimizing the use of their medical and pharmaceutical assets.

Multi-Parameter Patient Monitoring Market is Booming Worldwide by 2033 | Growth, Share, Demand and Analysis Forecasts

In 2023, the multi-parameter patient monitoring market is expected to be worth US$ 4.8 billion and is estimated to reach US$ 7.2 billion by 2033. The rise in demand for early diagnosis and treatment of chronic diseases around the world, as well as the high demand for real-time patient monitors in critical care units to make better clinical decisions on the spot, and to document changes in a patient’s condition at every stage, are expected to drive market growth.

The multi-parameter patient monitors are commonly utilized to improve patient health in both in-patient wards and intensive care units (ICU). Monitoring is a vital component of critically ill patients, particularly in emergency rooms, because the functional response to critical illness is directly linked to the outcome. Monitoring critically ill patients with multi-parameter monitors enable physiological reserve measures and reflects the success of treatment interventions.

Wearable gadgets and wireless communication technology advancements for medical telemetry have expanded the scope of monitoring solutions for patients both within and outside of hospital facilities. Such technical improvements allow for the rapid recording and transmission of data from a patient’s gadget to a healthcare practitioner, reducing the duration of evaluation and treatment.

The emergence of wireless networks in the healthcare sector, such as Radio Frequency Identification (RFID) and Medical Body Area Networks (MBAN), has changed patient health diagnostic processes while generating no discomfort due to their wireless architecture. This helps to monitor heart rate, blood pressure, body temperature, and oxygen levels in the body.

The introduction of single-use portable gadgets has expanded patient flexibility while also lowering the cost of frequent hospital visits. Moreover, the growing demand for home-based medical treatments for the elderly population is driving the demand for these portable patient monitoring devices that are simple to use.

Key Takeaways:

The multi-parameter patient monitoring market is estimated to register a CAGR of 4.0% from 2023 to 2033.

The multi-parameter patient monitoring market is dominated by North America in 2023.

China is the leading revenue contributor in the multi-parameter patient monitoring market in the Asia Pacific region.

Portable multi-parameter monitor is likely to thrive in the modality category due to its increasing popularity among geriatric population.

For More Information: https://www.futuremarketinsights.com/reports/multi-parameter-patient-monitoring-market

Key Developments

In December 2019, Nihon Kohden Corporation introduced its Life Scope SVM-7200 series vital sign monitors for outpatient facilities in the United States.

Schiller AG and VISUS, a prominent provider of image management systems, formed technical cooperation in January 2015. This collaboration improved the integration and presentation of E.C.G. data in the image data management system (JiveX Medical Archive).

Nihon Kohden Corporation announced the formation of a sales subsidiary, Nihon Kohden Latin America S.A.S., in March 2014 in order to grow sales in Mexico, Central America, South America, and the Caribbean. The new sales subsidiary complements and improves the sales network throughout Central and South America.

Key Players:

Koninklijke Philips N.V.

GE Healthcare

Drägerwerk AG & Co. KGaA

Medtronic plc

OSI Systems Inc.

Nihon Kohden Corporation

MASIMO

Contec Medical Systems Co. Ltd.

General Meditech Inc.

Mindray Medical International Limited

Schiller AG

So, Toasty, how's it going having a cat with diabetes?

Well, it involves a lot more cats in space helmets than I expected, and a lot fewer insulin injections. (So far.)

The big gray boy, Tico, has diabetes. The two girls do not, but they are currently the only ones eating prescription diabetes food, served inside their little cat-stronaut suits (as Ms. Avocado dubbed them). It's a long story. We'll get there.

When we got Tico's diagnosis, the vet said the path to improved Tico health was:

New diet (switch to wet food, and give more limited portions)

Insulin injections 2x/day

Regularly monitor blood glucose levels

But then I got the additional piece of information that you aren't supposed to give a cat insulin unless they've just eaten at least 1/4 of their daily food portion pretty recently. Otherwise, you are overdoing the insulin, and they can get very sick. And unfortunately, my cats are free-feeders, and Tico is a grazer who eats approx two (2) kibbles each time he visits the food bowl. So, new goals and new priorities:

Get Tico to eat enough dry food at one time (2x/day) to give insulin

Start insulin injections

Regularly monitor blood glucose levels

Switch to wet food once he's eating enough (I also found out that they food they're currently on is among the most highly recommended dry foods for diabetic cats, so it's less urgent)

I tried switching them to eating 2x/day, removing their food bowls at other times. They got very frantic, and the two girls would immediately scarf down food whenever food was present. However, Tico got stressed and just stopped eating. The vet was more worried about him not eating than she was about whether he was getting insulin immediately. So, new plan:

Get Tico to eat again and stop stressing

More gradually switch to eating dry food 2x/day

Once he is eating enough at one time, start insulin injections

Regularly monitor blood glucose levels

Switch to wet food gradually

At the advice of the vet, we went back to free-feeding temporarily until Tico calmed down. At her advice, I also put out some of the prescription wet food, separately from his normal food, just to see if Tico might like it. The girls swooped in and gobbled it up. Tico wanted nothing to do with it. Sigh.

Oh, also in here, we tried to take Tico in to get a demonstration of how to give him insulin, and to run some follow up tests -- but I ended up just taking an impressive neck scratch into the vet and seeing a demonstration on a stuffed cat instead, and then watching some YouTube videos along with the vet tech, ahaha. Also, the exam room only had pictures of dogs up on the walls, and no cats at all??

Oh, and also CHICKEN representation before cats??!? Rude.

A couple days later, Tico did seem to chill out and start eating again after a couple days of free-feeding (while continuing to disdain the wet food). So the vet suggested we then try to do mealtimes 4x/per day, and more gradually wean down to two -- and that I "carefully monitor" Tico's intake and only start injections once he's reliably eating plenty.

Monitoring anything with one ravenous cat (Winter) and two extremely wary ones (Tico and Bennet) is difficult -- and controlling portions would be even more so. But Past Me had cleverly ordered SureFeed smart feeders -- the cat-stronaut helmets! -- and they arrived earlier this week. They have RFID readers that pair with each kitty's microchip, and then they only open the lid when that kitty is trying to eat. And then they send your phone notifications like this:

So new goals:

0. Make sure the cats were microchipped when they were kittens (DONE, thank god; the alternative would be to train them to wear collars now with little ID chip tags hanging off them, and my kitties would NOT enjoy collars)

Set up new space helmet feeders, but with all the "smart" features like the automatic lids turned off

Watch kitties run away and hide for a good long while

Watch kitties giraffe their necks out to max length and sniff feeders very suspiciously

Put the feeders into pairing mode (lol) and then lure kitties to the feeders using their new diabetes-friendly treats (mmmm, dehydrated salmon), so that the feeders can register their microchips

Watch kitties get hungry and very grudgingly start to eat from these new strange feeders, still without any of the "smart" features turned on... including watching them sometimes fish the food out with their paws so that they don't actually have to put their heads into the scary space helmets <- we're here right now

(Next step) Use the space helmet feeders' Training Mode to slowly start moving the automatic lids (which will eventually cover up the bowls) a little bit whenever the feeder detects that the correct kitty is nearby

Watch the kitties jump into the air and run and hide (presumably)

Get the kitties gradually used to the lids moving more and more

Eventually, the automatic lids will cover the bowls most of the time, and the feeders will only open the lids for the correct kitty

YAY! Now we can do per-kitty portion control and monitoring!!

Once Tico is relaxed and eating enough at one time, start insulin injections

Regularly monitor blood glucose levels

Switch Tico to wet food gradually (the girls are VERY enthusiastic about the wet food, lol, which is not a bad thing -- they can all make that switch. The only reason I didn't give them wet food before was that I was gone a lot and just leaving out food for them, and that works better with dry food)

Practice wrapping Tico up in a towel regularly and picking him up/moving him a little bit now and then, so that he's calmer about it and easier to take to the vet in the future (and also keep putting treats in his carrier in the hopes that he starts wandering in and out of there more of his own accord) <- actually we're kind of doing this now, too. But he hates it, and I don't want him to get so jumpy that he won't sit still for brushing + injections, so we're not pushing it

The one time my lil dude voluntarily got into his carrier.

While we're working our way up to the stabby steps (11 & 12), I'm simulating insulin injections to get Tico used to the ritual of it. He's extremely hard to catch or hold in place when I want to put into a carrier (or god forbid try to trim his nails or something), but otoh he LOVES sitting next to me on the couch and getting brushed with something toothy:

"Hey Tico -- do you want THE BRUSH???"

He comes over excitedly quivering his lil tail any time and meowing bossily any time I offer him the brush. (He's a little masochist who just wants all his hair pulled out all the time -- we had to stop brushing him as much as he wanted because he started getting little bald patches, so now it's a special treat lol.) And then he jumps up onto the couch and loafs right next to me, facing away from me, so I can easily brush him -- which is also exactly where I would want him to be if I were to give him an injection. So I've been brushing him a little bit after meals and pinching his scruff, and it's been going well. I think he'll actually adapt quite easily to my doing the toothy brushing + a quick jab in the scruff (which cats hardly feel).

Doing the glucose monitoring might be harder. But I am not worrying about that step yet, aside from having ordered a home glucose monitoring system for cats! (Also not worrying yet about how I have to catch him in 12 days to board him at the vet, where they will run a few more tests on him and give him insulin, assuming he eats and doesn't just go on hunger strike due to the stress of being boarded for the first time ever.)

At least we caught the diabetes early, so even though I should be giving him insulin as soon as possible, it's not as dire as it could be.

But. Yeesh. This is all kind of a lot! I remember all this being much easier for my parents when their kitty got diabetes, because he was the world's most nonchalant cat. Mine are not that. :) But we shall get through this time of stressful transitions, and then a lot of this will hopefully be much easier.

Pet Tech Market Analysis, Development Status, Business Growth and Regional Forecast Till 2035

New York – March 10, 2023 - Research Nester’s recent market research analysis on “Pet Tech Market: Global Demand Analysis & Opportunity Outlook 2035” delivers a detailed competitors analysis and a detailed overview of the global pet tech market in terms of market segmentation by type, product, application, end use, distribution channel and by region.

Rise in Prevalence of Disease Among Pets to Boost the Growth of Global Pet Tech Market

The global pet tech market is estimated to grow on account of rise in prevalence of disease among pets. Many diseases affect pets, most of which go unrecognized. For instance, congestive heart failure (CHF) is comparatively common in dogs. Around 9% of all canines and about 74% of older dogs have some form of heart illness.

There are numerous potential causes for the emergence of CHF. Some dogs are born with congenital cardiac issues that contribute to this sickness, albeit the symptoms of this ailment may not appear for years. As a result, there is an increasing need for various wearable animal gadgets and AI-assisted technologies, which is further expected to drive market expansion.

Moreover, surge in adoption of pet is also anticipated to boost the market growth. Around 18 million dogs were kept as pets in India in 2018. It was predicted that there would be more pets than 30 million by the end of 2023. Interaction with animals has been demonstrated to lower blood pressure and cortisol levels, a hormone associated to stress.

Other studies have shown that interacting with animals could elevate mood, reduce loneliness, and foster a sense of community. Therefore, this may be the main driver of the increase in pet adoption. Also, there has been an increase in the transmission of disease among pets, which has raised concerns about the health of the animals. As a result, there is a rising need for examination, which is expected to fuel the market for pet tech.

Some of the major growth factors and challenges that are associated with the growth of the global pet tech are:

· Growing Prevalence of Internet

· Rise in Lost Pet Cases

Challenges:

Owners who use pet-related devices must also deal with unanticipated problems. Even, if the training collar has a remote, it could occasionally not work. For instance, the batteries may deplete or the remote control could stop operating at any time. There could be further problems, as when food is served insufficiently or at the inappropriate times.

There are many possible ways that technology could go wrong, so when these problems do arise, people might find them annoying. As a result, it is predicted that this factor would slow market expansion. Moreover, there is a possibility that this pet tech may also suffer from electrical issues as many tech products do operate on electricity. Hence, owing to the shortage of electricity this product couldn’t function.

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By type, the market for pet tech is segmented into RFID, GPS, and sensors. Amongst these segments, the RFID segment is anticipated to garner the largest revenue by the end of 2035, backed by rising need to monitor the temperature, heart rate, and more, of the pet. Further, the obesity prevalence among pets is also growing. Hence, owing to this, the need to monitor calorie intake is also rising, further boosting the segment growth.

Also, farmers are using it more frequently to track their livestock. When an animal comes within range of the RFID reader, a radio signal from the reader's antenna activates the RFID chip, enabling radio frequency identification, also known as RFID. After that, the chip sends back a signal with the animal's unique identification number. Reader information might be used by an animal tracking computer. Farmers and ranchers use tags to track a variety of factors, including medication dosage, feed output, weight, and milk production.

By region, the North America pet tech market is estimated to generate the highest revenue by the end of 2035. The growth of the market in this region can be attributed to rising disposable income of the people which is further influencing people to invest more on intelligent and smart pet products such as smart collars, feeders, and more, along with growing adoption of rescue pets.

Additionally, it is projected that the rise in pet illnesses would encourage pet owners to invest in smart pet technology and monitor their pets' physiological processes including breathing, heart rate, and sleep. This is expected to boost growth for the North American pet tech market in the region throughout the course of the projected year. Also, with an increasing demand for pet collars that enable better training in animals, the market in this region is expected to expand significantly during the ensuing years.

This report also provides the existing competitive scenario of some of the key players of the global pet tech market which includes company profiling of GoPro, Inc., FitBark Inc., Garmin Ltd., CleverPet Inc., Scollar Personalized Pet Care, Tractive, Mars Incorporated, Lupine Pet, Motorola Solutions Inc., and Wagz Inc.

Know Labs Study Validates Technical Feasibility of its Non-Invasive Glucose Monitoring Sensor

Know Labs Study Validates Technical Feasibility of its Non-Invasive Glucose Monitoring Sensor. Study demonstrates the Bio-RFID™ sensor can deliver stable, repeatable results in predicting blood glucose concentrations using the Dexcom G6® as a reference device. Seattle, May 05, 2023 - Know Labs, Inc. (NYSE American: KNW), an emerging developer of non-invasive medical diagnostic technology, today announced the results of its latest technical feasibility study titled, “Technical Feasibility of a Novel Sensor for Non-Invasive Blood Glucose Monitoring Compared to Dexcom G6®.” Know Labs is presenting these results today, May 5, at the American Association of Clinical Endocrinology (AACE) Annual Meeting in Seattle, WA. From December 2022 through February 2023, Know Labs conducted a series of internal studies to validate the technical feasibility of its Bio-RFID™ sensor technology at quantifying blood glucose concentration (BGC) in five healthy participants, using the Dexcom G6® as a reference device. Bio-RFID is a novel platform technology using electromagnetic energy in the form of radio waves to non-invasively capture molecular signatures and converts them into physiologically meaningful information. The purpose of this technical feasibility study was to demonstrate hardware and software infrastructure stability and to collect additional data to determine the accuracy of the sensor at quantifying BGC in vivo non-invasively using radio frequency, by means of training a neural network (NN) model to predict readings of the Dexcom G6® as a proxy for BGC. Know Labs Study Validates Technical Feasibility of its Non-Invasive Glucose Monitoring Sensor. Image from KnowLabs In the aggregate – across five individual participants, 46 tests, and 92 samples, which collected 4.7 million data points per sample or roughly 430 million data points for all samples – the study resulted in a mean absolute relative difference (MARD) of 20.6% and performed with 46% of predictions within the U.S. Food and Drug Administration’s (FDA) recommended limit for accuracy for new blood glucose monitors. “We have successfully completed our foundational studies, we have a stable sensor that delivers repeatable results, and we have developed software infrastructure to manage and interpret large, novel datasets,” said Steve Kent, Chief Product Officer at Know Labs. “As you increase sample size, it is expected that there are changes in accuracy, resulting from variability in testing conditions, biological diversity, and other factors. This is the goal of expanded data collection, and we will continue to share results as we collect more high resolution data, from more participants, across more testing scenarios.” During the data collection period, participants placed their forearms on the Bio-RFID sensor and consumed liquid D-Glucose to simulate a glucose spike. Participants' BGC was monitored for three hours while readings from the Bio-RFID sensor and the Dexcom G6® were simultaneously logged. Data were collected on a continuous basis, using sweeps across the 500 MHz to 1500 MHz range at 0.1 MHz intervals, collecting values at 10,001 frequencies per sweep. Know Labs then used these data from the Bio-RFID sensor to train a NN model to predict BGC readings of the Dexcom G6® reference device. “Today’s methods of testing BGC come with several disadvantages, from the pain of finger pricks and inserting probes for continuous monitors to the high cost and environmental waste these methods produce,” said Ron Erickson, CEO and Chairman at Know Labs. “This study demonstrates our progress toward getting the first FDA-cleared non-invasive glucose monitoring device in the hands of the nearly 40 million people living with diabetes in the U.S. We’ve achieved so much over the last several months. We’ve refined data collection methods and increased our participant population, with our dataset growing from 3 in our exploratory study to 92 in this study, a 30-fold increase in the sample size. To-date, we’ve collected 1.4 billion data points that are now being used to refine our glucose value prediction algorithm.” This technical feasibility study is part of ongoing clinical research that Know Labs is conducting as the company prioritizes validation of the Bio-RFID technology. A Technical Report of the company's Proof of Concept (N=1) results is publicly available at www.knowlabs.co/research-and-validation. Know Labs, Inc. is a public company whose shares trade on the NYSE American Exchange under the stock symbol “KNW.” The Company’s technology uses spectroscopy to direct electromagnetic energy through a substance or material to capture a unique molecular signature. The Company refers to its technology as Bio-RFID™. The Bio-RFID technology can be integrated into a variety of wearable, mobile or bench-top form factors. This patented and patent-pending technology makes it possible to effectively identify and monitor analytes that could only previously be performed by invasive and/or expensive and time-consuming lab-based tests. The first application of our Bio-RFID technology will be in a product marketed as a non-invasive glucose monitor. It will provide the user with real-time information on blood glucose levels. This product will require U.S. Food and Drug Administration clearance prior to its introduction to the market. Read the full article

10 IoT App Ideas for Startups in 2023

In recent years, the Internet of Things (IoT) has been taking the tech industry by storm. With its potential to connect everything from cars to home appliances, IoT is expected to revolutionize the way we live and work. For startups looking to enter the IoT market, developing an IoT app can be a lucrative opportunity. Here are list of IoT app ideas for startups to consider in 2023:

Smart Home Security:

Create an IoT app that connects to smart home devices such as cameras, door locks, and motion sensors to provide enhanced security features.

Health Monitoring:

Develop an app that connects to wearable devices such as smartwatches to track and monitor users' health metrics such as heart rate, blood pressure, and sleep patterns.

Smart Agriculture:

Create an app that utilizes IoT sensors and data analysis to optimize crop yield, water usage, and other farming processes.

Environmental Monitoring:

Develop an IoT app that monitors and tracks air quality, water quality, and other environmental factors.

Supply Chain Management:

Create an app that connects to IoT sensors and devices to optimize supply chain processes such as inventory management and transportation.

Energy Management:

Develop an app that connects to smart home devices to optimize energy usage and reduce utility costs.

Smart Parking:

Create an app that utilizes IoT sensors to help users find available parking spaces in real-time.

Smart Retail:

Develop an app that connects to IoT devices such as beacons and RFID tags to provide a personalized shopping experience for customers.

Smart Waste Management:

Create an app that utilizes IoT sensors and data analysis to optimize waste collection and recycling processes.

Smart City Management:

Develop an app that connects to IoT sensors and devices to optimize city services such as traffic management, waste management, and public safety.

In conclusion, IoT apps have the potential to transform various industries and create new opportunities for startups. By developing innovative IoT app ideas, startups can tap into this growing market and create value for customers. These 10 IoT app ideas can serve as inspiration for startups looking to enter the IoT space in 2023.

RFID Blood Monitoring Systems Market Fastest Growing Segment Over the Forecast Period 2022

Jan 22, 2021: Industry Insights

The global RFID blood monitoring systems market size was estimated at USD 104 million in 2014. Rising demand for efficient management system regarding blood & related products and growing awareness pertaining to minimize transfusion errors in medical process are some of the key factors driving RFID blood monitoring systems market. Rapidly consolidating healthcare sector and increase in volume of blood & related products inventory is further boosting up the demand for this technology in healthcare industry.

Technological advancements in RFID systems will not only provide identification details but also provide location information on a real time basis, which will further boost demand among end-users for these devices. Increase in R&D activities for the development of new management solutions and rising concerns for patient safety is expected to propel the growth of RFID blood monitoring systems. Growing adoption of RFID technologies by the hospitals and blood banks particularly in blood freezers and refrigerators further surges demand for this technology.

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Some of the other factors driving the growth of the market are favorable regulatory policies for the approval of RFID technologies and rising trend of privatization of healthcare infrastructure that led to the introduction of modern technologies in the healthcare settings. In 2013, FDA approved iTrace which is a RFID-based tracking system that can be used in blood banks systems.

Product Insights

Radio frequency identification held majority of the market share in terms of revenue, with over USD 60 million in 2014 pertaining to the factors such as growing concerns for patient safety, increasing adoption of smart medical devices, favorable government initiatives, and rising need for reduction in healthcare cost. In addition, various application of RFID in healthcare system further drive the demand over the forecast period.

Radiofrequency identification tags held the significant market share owing to the demand of technologically advanced products such as alternative tags and sensory tags designs that uses Smart Active Label Technology (SAL) which is less susceptible to metal and liquid. In addition, it maximizes the profitability of medical facilities that is expected to further boost up its demand.

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End Use Insights

Blood Banks emerged as the largest segment and was valued at over USD 85 million in 2014. Increasing need for patient safety, minimization of transfusion errors & wastage of blood products are amongst the key factors owing to the growing usage of RFID technologies in the blood banks. In addition, increasing number of blood banks and rising inventory of blood and blood products further expected to drive the demand of RFID technologies in blood banks. RFID technology helps in creating an efficient supply chain of blood products, right from the collection point to its delivery to the hospitals or clinical settings.

Regional Insight

North America dominated the regional segment in 2014 followed by Europe owing to rising number of blood banks, sophisticated healthcare infrastructure, growing demand for operational efficiency and favorable government initiatives. Increasing number of funding for the research activities in RFID technologies attribute to its growth in the region. Asia pacific region is expected to be the fastest growing segment over the forecast period. The growth in the region is driven by the factors such as improved healthcare infrastructure and increased penetration of RFID blood monitoring system. Low cost of RFID components such as original equipment manufacturing (OEM) services provided by China offers huge potential of RFID technologies in Asia pacific market.

Competitive Insights

Some of the key participants of enteral feeding device market include, Abbott; Nestle; Danone, Inc.; Fresenius SE & Co. KGaA; Kimberly-Clark Corporation; Boston Scientific Corporation; Conmed Corporation; Moog, Inc.; Covidien Plc.; Cook Medical and Amsino International Inc. and others.

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