#Ablation Technology
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Unlocking precision and efficiency, the Ablation Technology Market reshapes medical treatments worldwide. Explore the innovations driving improved patient care and paving the way for future therapeutic approaches.
#Ablation Technology Market#Ablation Technology Industry#Ablation Technology#Ablation Technology Market size#Ablation Technology Market share#Ablation Technology Market demands#Ablation Technology Market trends#Ablation Technology Market cost#Ablation Technology Market growth
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This is How Leading Companies are Dominating Global Ablation Technology Market
The competitive landscape includes the analysis of the key growth strategies adopted by major players between 2017–2021 to expand their global presence and increase their market shares in ablation technology market.
Major Growth Driving Factors:The growing elderly population has also driven the incidence of target conditions and contributed to the demand for effective treatment. However, the…
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Navigating the Evolving Ablation Technology Market Landscape towards 2034
The global ablation technology market size is estimated to be valued at US$ 6.2 billion in 2024. The demand for ablation technology is expected to witness a robust CAGR of 8.9% from 2024 to 2034. By 2034, sales of ablation technology are anticipated to reach a valuation of US$ 14.6 billion.
The rise in chronic illnesses is expected to boost the market expansion. Research and development efforts focused on state-of-the-art ablation technologies are propelling the market’s growth.
Emerging countries like South Korea, China, and India are making significant strides in medical technology. There has been an increase in cancer, heart disease, liver problems, and elderly individuals in these areas. This is a great chance for the ablation technology to continue. These nations have a sizable patient population, which presents opportunities for ablation technology market players.
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Other factors transforming the market share of ablation technology include minimal regulatory obstacles, infrastructure, and rising healthcare spending. Local and regional firms make major investments in research and development, enhancing the ablation technology industry.
One factor impeding market expansion is patients’ and healthcare providers’ ignorance of the advantages and adoption of ablation technologies. The upfront expenditures associated with ablation technology are substantial for patients and healthcare providers. The methods come at a cost that prevents wide adoption of ablation technologies, especially in areas with tight funding.
Regional Outlook
Growing investments in healthcare infrastructure are driving the ablation technology market in Asia Pacific, with developing nations like China and India exhibiting strong potential for growth.
Europe is at the forefront of the adoption of innovative ablation technologies due to its strong emphasis on research and development, which has created an environment where technological developments are constant.
As a center of global innovation for medical technology, North America supports a competitive environment with several research and development initiatives that accelerate the ongoing advancement of ablation technologies on the market.
“Due to the growing need for minimally invasive procedures in various medical specialties, the ablation technology market is expected to rise. The ablation technology vendors have opportunities in the shifting landscape due to technological improvements and growing awareness, which provide an optimistic outlook,” opines Sudip Saha, managing director at Future Market Insights (FMI) analyst.
Key Takeaways
The radiofrequency ablators segment in the product category is anticipated to evolve at a CAGR of 6% from 2024 to 2034.
In the application category, the cardiovascular disease treatment segment is expected to accelerate at a CAGR of 4% through 2034.
Sales of ablation technology in the United States are anticipated to surge at a CAGR of 3% through 2034.
The United Kingdom’s ablation technology market will likely develop at a CAGR of 8% through 2024.
China’s ablation technology sales are expected to surge at a CAGR of 7% until 2034.
South Korea’s ablation technology industry is anticipated to boost at a CAGR of 7% over the forecast period.
Japan’s ablation technology market is anticipated to exhibit a CAGR of 6% through 2034.
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Competitive Landscape
The ablation technology market is characterized by intense competition fueled by the search for innovative solutions and technological improvements. Prominent ablation technology vendors are concentrating on research and development to improve their product offerings and keep a competitive edge.
Regional expansion, strategic alliances, and regulatory compliance are a few variables that impact market dynamics. A wide spectrum of ablation technology providers striving for dominance in the quickly changing ablation technology sector characterizes the competitive landscape.
Prominent Ablation Technology Manufacturers
St. Jude Medical Inc.
Medtronic plc
Boston Scientific Corporation
AngioDynamics, Inc.
AtriCure, Inc.
Conmed Corporation
Olympus Corporation
Smith and Nephew plc
BTG plc
Johnson and Johnson
Accuray Incorporated
C.R. Bard, Inc.
Varian Medical Systems, Inc.
Elekta AB
Misonix, Inc.
Newest Advancements
In October 2022, the C2 CryoBalloon Ablation System was introduced in Canada to treat Barrett’s esophagus. PENTAX Medical, a manufacturer of endoscopic products for both therapeutic and diagnostic purposes, used it first.
In March 2022, the United States Food and Drug Administration granted clearance to Quantum Surgical 510(k) for its Epione robot, capable of planning, delivering, and verifying tumor ablation as a cancer treatment.
Key Segments
By Product:
Radiofrequency Ablators
Temperature-Controlled Radiofrequency Ablators
Fluid-Cooled Radiofrequency Ablators
Robotic Catheter Manipulation Systems
Laser/Light Ablators
Excimer Laser Ablators
Cold Laser Ablators
Ultrasound Ablators
Ultrasonic Surgical Ablation Systems
High-Intensity Focused Ultrasound Ablators
Extracorporeal Shockwave Lithotripsy Systems
Magnetic Resonance-Guided Focused Ultrasound Ablators
Electrical Ablators
Argon Plasma/Beam Coagulators
Irreversible Electroporation Ablators
Cryoablation Devices
Tissue Contact Probes
Tissue Spray Probe
Epidermal and Subcutaneous Cryoablation Devices
Microwave Ablators
Hydrothermal/Hydromechanical Ablators
By Application:
Cardiovascular Disease Treatment
Cancer Treatment
Liver Cancer
Kidney Cancer
Prostate Cancer
Lung Cancer
Bone Metastasis
Breast Cancer
Ophthalmological Treatment
Pain Management
Urological Treatment
Orthopedic Treatment
Cosmetic/Aesthetic Surgery
Gynecological Treatment
Others
By End Use:
Hospitals
Ambulatory Surgical Centers
Ablation centers
Others
By Region:
North America
Europe
Asia Pacific
Middle East and Africa
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Breaking Boundaries in the Ablation Technology Market
#Ablation Technology Market#Ablation Technology Industry#Ablation Technology Market Size#Ablation Technology Market Share#Ablation Technology Market Growth#Ablation Technology Market report#Ablation Technology Market Trends#Ablation Technology Market Demands
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Ablation Technology Market May Set New Growth Story
Latest business intelligence report released on Global Ablation Technology Market, covers different industry elements and growth inclinations that helps in predicting market forecast. The report allows complete assessment of current and future scenario scaling top to bottom investigation about the market size, % share of key and emerging segment, major development, and technological advancements. Also, the statistical survey elaborates detailed commentary on changing market dynamics that includes market growth drivers, roadblocks and challenges, future opportunities, and influencing trends to better understand Ablation Technology market outlook.
List of Key Players Profiled in the study includes market overview, business strategies, financials, Development activities, Market Share and SWOT analysis:
Medtronic PLC (Ireland), Biosense Webster, Inc. (United States), St. Jude Medical, Inc. (United States), Boston Scientific Corporation (United States), Angiodynamics, Inc. (United States), Atricure, Inc. (United States), Conmed Corporation (United States), Olympus Corporation (Japan), Smith & Nephew (United Kingdom), Galil Medical Inc. (United States).
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Brief Overview on Ablation Technology:
Ablation is an established treatment strategy for a number of different cardiac arrhythmias. In the past decade, two main areas of expansion have been atrial fibrillation (AF) and ventricular tachycardia (VT) ablation associated with structurally abnormal hearts. It can treat atrial fibrillation. When combined with a full treatment program, catheter ablation can improve your quality of life and eliminate or reduce the uncomfortable symptoms of atrial fibrillation such as shortness of breath, tiredness, or weakness. In parallel to the growing role of catheter ablation for AF and VT, several new technologies have been developed that are intended to increase the safety and the success of the procedure. Areas of development include novel catheter designs, novel navigation technologies, and higher resolution imaging techniques. The aim of this review is to provide an overview of novel developments in AF ablation and VT ablation in patients with structural heart disease.
Key Market Trends:
Increasing Number of Hospitals, Surgical, And Ablation Centers
The Use of Ablation Technology for the Treatment of Cancer
Opportunities:
High Prevalence of Cardiovascular Diseases Especially Atrial Fibrillation
High Usage Rates of Electrical Ablation in the Treatment of Disease
Market Growth Drivers:
Rising Incidence of Atrial Fibrillation across the Globe
Increasing Number of Ablation Procedures
The Large Population Base
The Rising Prevalence of Cancer
Challenges:
The Availability of Various Radiation Devices
Segmentation of the Global Ablation Technology Market:
by Type (Radiofrequency Ablation, Laser/Light Ablation, Ultrasound Ablation, Electrical Ablation, Cryoablation), Application (Hospitals, Clinics, Others), Function Type (Automated/Robotic, Conventional Ablation Devices), End-Use (Cardiovascular Disease Treatment, Cancer Treatment, Ophthalmologic Treatment, Pain Management, Gynecological Treatment)
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Geographically, the following regions together with the listed national/local markets are fully investigated:
• APAC (Japan, China, South Korea, Australia, India, and Rest of APAC; Rest of APAC is further segmented into Malaysia, Singapore, Indonesia, Thailand, New Zealand, Vietnam, and Sri Lanka)
• Europe (Germany, UK, France, Spain, Italy, Russia, Rest of Europe; Rest of Europe is further segmented into Belgium, Denmark, Austria, Norway, Sweden, The Netherlands, Poland, Czech Republic, Slovakia, Hungary, and Romania)
• North America (U.S., Canada, and Mexico)
• South America (Brazil, Chile, Argentina, Rest of South America)
• MEA (Saudi Arabia, UAE, South Africa)Furthermore, the years considered for the study are as follows:
Historical data – 2017-2022
The base year for estimation – 2022
Estimated Year – 2023
Forecast period** – 2023 to 2028 [** unless otherwise stated]
Browse Full in-depth TOC @: https://www.advancemarketanalytics.com/reports/55-global-ablation-technology-market
Summarized Extracts from TOC of Global Ablation Technology Market Study Chapter 1: Exclusive Summary of the Ablation Technology market
Chapter 2: Objective of Study and Research Scope the Ablation Technology market
Chapter 3: Porters Five Forces, Supply/Value Chain, PESTEL analysis, Market Entropy, Patent/Trademark Analysis
Chapter 4: Market Segmentation by Type, End User and Region/Country 2016-2027
Chapter 5: Decision Framework
Chapter 6: Market Dynamics- Drivers, Trends and Challenges
Chapter 7: Competitive Landscape, Peer Group Analysis, BCG Matrix & Company Profile
Chapter 8: Appendix, Methodology and Data Source
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#Global Ablation Technology Market#Ablation Technology Market Demand#Ablation Technology Market Trends#Ablation Technology Market Analysis#Ablation Technology Market Growth#Ablation Technology Market Share#Ablation Technology Market Forecast#Ablation Technology Market Challenges
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The global Medical Ablation Technology market size is projected to reach US$ 170.4 million by 2030, from US$ 122 million in 2021, at a CAGR of 5.3% during 2022-2030.
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Radio Frequency Ablation Device Market Overview and Insights during 2022-2028
Radiofrequency Ablation is a medical treatment that includes using heat generated by medium frequency alternating current (in the 350–500 kHz range) to ablate a section of the electrical conduction system of the heart, tumour, or other defective tissue. RFA is usually done as an outpatient treatment with the use of local anaesthetics or conscious sedation anaesthesia. When given using a catheter, it's known as radiofrequency catheter ablation. Radiofrequency current has two significant advantages over previously used low-frequency AC or DC pulses: it does not directly stimulate nerves or heart muscle, so it can often be used without general anaesthesia, and it is very specific for treating the desired tissue without significant collateral damage.
Higher frequency of cardiovascular illnesses including atrial fibrillation, rising incidence of cancer and discomfort in patients, and increased desire for minimally invasive treatments all contribute to market expansion. In addition, the use of ultrasonic ablation technology in RFADs is growing in popularity. The research on the Global Radio Frequency Ablation Device Market provides a comprehensive analysis of the industry. The research includes a detailed analysis of major segments, trends, drivers, constraints, the competitive landscape, and other important market aspects.
See more insights of the Complete Blog- https://cmi-latestreportorientedblogs.blogspot.com/2022/06/radio-frequency-ablation-device-market.html
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Some of the history of Zwo-nmu System Exploration by Mellanoid Slime Worm Space Programs.
A reminder of the Zwo-nmu Planetary System. The Sun, also called The Zwo-nmu (literally The Day Light) is a G8V main sequence star with many giant planets. Mellanus, called Gymnome by some of its inhabitants, is the homeworld of the Mellanoid Slime Worms--Eaurp Guz's people. Mellanus is a coorbital of Omen in a horseshoe orbit. Every 15 or so earth years, Mellanus approaches Omen, which moves it into a higher or lower orbit around the Sun.
This graphic is in a rotating reference frame following Omen. green circle is Omen's orbit in a non-rotating reference frame. Yellow circle is Mellanus' inner/short/summer/hot orbit. Purple circle is Mellanus' outer/long/winter/cold orbit. Blue and gray circles are the orbits of Cold Ember and Rabbit. Times are given in Earth days and distances in Earth-Sun-distances (astronomical units)
Omen is named, of course, as it represents drastic climate change--orbital seasons affecting both hemispheres for many years at a time.
With that reminder out of the way...
Zwo-nmu (the star)
extensive telescopic study from low mellanus orbit. The first solar telescope to enter orbit discovered the corona but was not set up to observe it properly, so follow-up missions had to be undertaken.
studied by the Cold Ember probes and by at least one dedicated "sun-scraper"
Cold Ember (the hot super-earth/sub-neptunian)
Of the five probes sent to Cold Ember at various times, only two have made it.
The second one to make it is an orbiter. It relies on stationkeeping propellant so its elliptical orbit always keeps its apoapsis on the night side of the planet, such that it can spend time in the shadow to keep cool. Within a few days of it running out of stationkeeping fuel it will begin to overheat. There are proposals to send a Rescue Shuttle up to resupply and repair the probe, but the strict rules about use of alien spacecrafts in the mellanoid space program make that difficult.
Rabbit
Visited by 2 robotic probes--a flyby and a short-lived orbiter. A lander/rover is planned, but doesn't have the same priority as the Omen Development Program and the Ice Giants Exploration Program.
Mellanus Orbit
At its peak, Mellanus had thousands of satellites and dozens of space stations, but a near-miss with ablation cascade (see: the movie Gravity (2013)) that was only averted thanks to the recently installed phaser network has lead to many restrictions being put in place on the number and function of satellites. Early in the history of mellanoid space exploration, there was not much automation available. Satellites had to be crewed, and so there were many space stations, and when automation happened, those space stations grew into constellations of satellites. Telecommunications constellations were the real culprit, with several competing agencies, companies, and nations setting up their own independent constellations ranging from 10s to 1000s of satellites each. But now, subspace technology has rendered low-orbit communications satellites obsolete, and there are just a few dozen geosynchronous communications satellites, a GPS network, and the number of Mellanus observation satellites has been coralled.
One of the United Mellanus Space Program's current duties is the cleanup of low orbit, which is operated both by phaser blasts in an emergency and by crewed spacecrafts. Most of the space stations in mellanus orbit are specifically infrastructure intended to refuel these spacecrafts, since they need to be able to access a wide range of inclinations, and inclination changes are difficult to accomplish.
Other space stations include the constellation of orbital drydocks, which are all orbiting about a hundred kilometers apart from one another, and the Starbase, a very large rotating artificial gravity space station which was built between the 2340s and the 2360s, and serves as the space end of the interstellar spaceport.
Mellanus natural satellites
Mellanus has one permanent satellite, Ubbi, a 340 meter wide rubble pile which is thought to have once been another asteroid's moon, millions of years ago. It is just barely bright enough to be seen by a mellanoid who has expanded their eye to the greatest practical width, but it wasn't noticed to be a moving star until after the invention of the astronomical telescope and the popularization of sun-centrism. It was thought at first to be an asteroid, since it was discovered while Mellanus was passing through Omen's trojan cloud, but careful observations determined that it was a satellite in a stable circular orbit, and a careful observation of photographic plates and star charts indicate it's been orbiting Mellanus for at least hundreds of years. It's named after its discoverer.
Many early mellanoid space activities have used Ubbi as a target. There are dozens of probes. Sadly Ubbi is very resource poor, being poor in both volatiles that could be used for propellant and metals that could make it valuable. It's not even a useful science target, since one of the earliest missions to visit it was an impactor which essentially exploded Ubbi. It reformed again, but completely resurfaced, burying clues to its origin as a satellite. Ubbi is currently orbited by one derelict spacecraft and
There have been three temporary natural satellites of Mellanus to be visited by spacecrafts. All but one have entered Mellanus orbit only for a few months and were only visited by robotic probes. The largest one, Temma was three kilometers across and in an eccentric orbit that remained stable all the way up until two Omen conjunctions later, so it lasted for about 30-35 years. However, as a carbonaceous asteroid, it was rich in volatiles, and it was explored and settled extensively by all major space programs. The first crewed international interplanetary trips to Omen used fuel refined from Temma and brought down to low orbit.
The Omen Coorbitals (Trojans, Greeks, and Other Horseshoes)
Outside of Ubbi and Temma, the Coorbitals are the next step out into space. Mellanus occasionally has close encounters with coorbitals. Over time Mellanus and Omen together have corralled the coorbitals into very specific lanes. There are far fewer coorbitals around Omen than Glerbuh, or, say, Jupiter, because coorbital or not, Mellanus is still a planet. Most of the coorbitals are trojans, with the apsides neatly tucked in between the outer edge of Mellanus' sphere of influence in the low orbit, and the inner edge of Mellanus' sphere of influence in the high orbit. The Greeks--the trojans on the leading edge of Omen's orbit--are especially depleted. It's thought that Mellanus was once the only large object in the greek camp, but was perturbed onto its current horseshoe orbit billions of years ago. As a result, the greek camp is a hodge-podge of scattered objects from elsewhere in the system, whereas the trojan camp is comprised of more objects original to this part of the circumstellar disk. Each camp can answer different questions about the evolution of the Zwo-nmu system, and Mellanus' relation to it in particular. Ironically, even though the greek camp is Mellanus' original home, it's the trojan camp that is more relevant to studying Mellanus itself.
It is possible on any given year to send a spacecraft to visit Omen, Trojans, Greeks, or any other coorbital. However, the trajectories which take a minimum of fuel are only accessible 1-6 months or so before the closest approach with either object, and for crewed missions, less efficient but faster trajectories lasting only a month right around the close approach are preferred.
Outside of the Omen apparitions, the most active times for interplanetary spaceflight have historically been around the passing through the trojan clouds, which happens about 6 years before and after each Omen apparition. Starting from the low summer orbit, Mellanus passes the Trojan Camp. 6 years later, it reaches Omen and moves to the high winter orbit. 6 years after that, it passes the Trojan camp again. Then 15 years later, it passes the Greek Camp. 6 more years later, Omen appears large and Mellanus shifts to the summer orbit. 6 years later, it passes the Greek camp again. 15 years pass, and then we restart the cycle.
other horseshoe-coorbitals can be encountered at any time of year, but there's only a few of these known to exist.
Crewed missions to the other coorbitals have served as test flights for Omen missions, while also contributing meaningfully to planetary science as a whole. While asteroid exploration may not be exciting or glamorous, the use of trojan missions as testbeds has allowed a lot of groundbreaking work that otherwise might not have had any support to be performed.
Humans currently, in the real world 2020s, posses the propulsion technology and even, in principle, the industrial capacity to send humans to Mars. What we lack is a good idea of how to support humans on interplanetary spaceflight for many months or years at a time. A typical stay on the International Space Station is not even comparable to a Mars mission. That research is still underway. But we can go to the Moon. What's crucial is the relatively short turnaround time. A Moon mission may take only a week or two. The Artemis lunar missions will last longer, but not as long as a Mars mission would have to.
Absent a permanent moon of any substance, the Mellanoids are able to get their relatively short turnaround missions done thanks to the coorbitals. If Mellanus were still a trojan, it'd have emptied out the Greek Camp. Omen would never get particularly close, and it'd take over a year to make a round trip to it. It'd be just as hard to reach as Mars or the Main Asteroid Belt. But since Mellanus is in a horseshoe orbit, for about a year at a time every 6-15 years it is within spitting distance of some celestial body or another. Every 18-19 years that celestial body is the magnificent planet Omen with its own system of moons. When it's not Omen, it's the coorbital asteroids.
Propulsion wise it is not that much easier to reach the Omen coorbitals than it is for humans to go to Mars. You still have to escape Mellanus and keep accelerating on top of that.
But instead of bringing all of the comforts and necessities involved in the long-term habitation of space with you to a distant planet, you can get away with using capsules that are not much more advanced than what we were using in the Apollo era. The long term habitation problem is solved, leaving the only major problem left that of propulsion, of vehicle design. And since Mellanus is relatively small and they aren't shy about using nuclear rockets, the propulsion problem isn't that big of a deal.
in a way, Omen and the coorbitals are a crutch. By the 2340s Mellanoid space programs still had not undertaken crewed interplanetary missions beyond the coorbitals. But, at least in Star Trek, human spaceflights to Europa & Jupiter were being undertaken in the 2020s. These missions would have had to take years!
that said, there is a reason Omen has been such a focus--and it's not just because it is so culturally important.
The Omen System
Since the dawn of the Mellanoid space age, there have been six Omen apparitions.
Years given are Earth Years
1) 2300: Two nations launched robotic flyby attempts this year. One succeeded, but it was little more than a spinning photopolarimeter which could take a grainy image of Omen and a magnetometer which produced useful magnetic field readings.
2) 2315: Two failed atmosphere probes for Oldsky, one successful robotic lander on Rival, one successful robotic lander on Spark, and successful orbit insertion of a robotic Omen orbiter which continued to send back photos of Omen and its moons right through to the next conjunction. During the lifetime of this orbiter, Oldsky was conclusively shown to have complex life.
3) 2329: First crewed missions. There is a crewed landing on Rival, a crewed orbiter mission for Oldsky. It had originally intended to operate out of a small space station placed into Oldsky orbit a year in advance, but this station was covertly destroyed by Zaldans, and the orbiter mission was repurposed as a mere flyby, which fails, leading to first contact with Zaldans.
4) 2344: The most important year yet--the beginning of space archaeology. It's also the year asteroid Temma departs Mellanus and makes its own flyby of Omen.
5) 2358: International grand tour involving orbiters and landers on every planet including Oldsky. Leads to formation of United Mellanus Space Program.
6) 2373: Fission-impulse rockets have made regular interplanetary travel between Mellanus and Omen possible on any year.
7) 2387: Oldsky is now a colony of Mellanus.
Mellanus is on the border of the Zaldan sphere of influence, and with the increasing expansionism of the Cardassians and the tragedy of what they had begun to do to the Bajorans, the Zaldans desired military bases on the stars near their industrial colonies and their homeworld. These bases had to provide deuterium, so they needed to be located in a system with a gas giant, and also function as repair stations. The stars surrounding Mellanus were poor candidates--there are no M-class habitable planets around the nearby stars, and the only other gas giants were hot Jupiters or brown dwarfs which would make deuterium extraction difficult.
The Zaldans respected the non-interference directive, but not if it meant a gaping hole in their security. They would set up a military base on Omen's M-class moon Oldsky. There was an orbiting space station and a surface base, connected by cargo transporters and shuttlecrafts, staffed by military officers and a few civilian personnel, not unlike Deep Space Nine, but considerably more of a frontier for all involved. There was also a space station built in very low orbit of Omen, designed to scrape the atmosphere for deuterium to fuel freighters. These ships would be undetectable to the mellanoids as long as ships entering the system avoided activity during close encounters and all ships entering and leaving the system hid their photon wakes behind the Sun, resulting in fairly complex routing.
During the 2329 Omen apparition, a spacecraft that had been intended to fly by Omen had a severe failure, akin to Apollo 13. Still over a month from home, with no prospect but a horrible death, they were famously rescued by Commander Halen's ship, EZM-407, marking official first contact with the Zaldans. They were returned to Mellanus and the Zaldans finally landed, showing the world that not only were Mellanoids not alone in the universe, they weren't even alone in their own solar system.
Several ships visited Mellanus over the next few years on primarily diplomatic missions, but the Zaldans still kept hands-off, sharing only a minimum of information with the Mellanoids. Not many Zaldans had Halen's affinity for the slimes, and they saw mellanoids as lowly uncivilized savages--and their flowery polite diplomatic language only confirmed this to them. It wasn't before someone really stood up to them--a space program engineer who had gotten tired of standing in the sidelines while his people were being insulted--that the Zaldans finally found a glimmer of respect for the mellanoids.
There had been plans to fly a Mellanoid astronaut to Oldsky in exchange for allowing Zaldan researchers to visit Mellanus, and even early talks of embassies and sharing of the Omen infrastructure, when the Zaldans just… disappeared. Completely cut contact.
If sharing their solar system with rude bullies (who, yes, could have wiped them out a dozen times over yet decided not to so at least there's that) wasn't scary enough, those rude bullies disappearing without a trace was even scarier. On a scale greater than even the Apollo program, nations rushed to assemble their missions to visit Omen and Oldsky to figure out what happened to the Zaldan Military Base. Their robotic probes launched on off-years didn't return any answers--crewed exploration and actually landing mellanoids on Oldsky would be the only answer.
There was also the fact that recovering technology from Oldsky could potentially be transformative--the right technology in the wrong hands could destroy the world. This is spaceflight at its most competitive. This was no longer a game--recovering the alien technology was potentially life or death.
After the first contact with the Federation and the series of revolutions and reforms that lead to the current political situation, one of the main unifying rallying cries for mellanoids was the notion that they deserved the right to sovereign exploration of their own solar system. Outsiders--whether Zaldan, or Federation, or Dominion--would not develop any part of the system!
Ok, the Federation can provide some baseline infrastructure to protect Mellanus from invasion, but space exploration is OUR COMMON HERITAGE!
The current age of Mellanoid Space Exploration is characterized by extensive permanent infrastructure development. Since the 2360s, Mellanoids have been building research stations on Oldsky, Lake, and Rival. Setting up an industrial capability on another planet from scratch is hard to do, but Oldsky has a stable climate year-round and a breathable atmosphere. Much of Oldsky is a desert, and even the "humid" regions are quite dry, but it's still more habitable than literally any other planet in the solar system except for Mellanus, which makes it practical to build using traditional methods.
As of 2380, more people are living and working on Oldsky at any given moment than are doing so in Low Mellanus Orbit. Oldsky station visitors includes geologists, biologists, space archaeologists still studying what remains of Zaldan activity on Oldsky, civil engineers, aerospace engineers, construction workers, miners, marine biologists, submarine helmcrew, aircraft pilots, spacecraft pilots, rover drivers, doctors, astronomers, and even a few tourists selected by raffle.
Propellant infrastructure has been established to keep the fast interplanetary rockets zipping along. At this point, it is possible to stay on Oldsky permanently, but so far, all visitors to Oldsky are temporary, and on years when Omen is inaccessible even with nuclear-fission-impulse rockets (i.e, when the Sun is between it and Mellanus), only a skeleton crew remains to maintain the stations.
Oldsky will probably not have its own self sufficient industry and capacity for its own space program any time soon, but it does have a spaceport serviced by reusable launch vehicles.
Phaser-thermal rockets are used for heavy lift launches from Mellanus these days, but conventional chemical rockets are still used on Oldsky, fueled by hydrogen and oxygen split by electrolysis. There is an oil refinery on Oldsky, so kerosene/oxygen rockets are possible too.
things remain somewhat low-tech on Oldsky. Imported vehicles can be powered by batteries, but there aren't let any lithium mines on Oldsky--good deposits have yet to be discovered--so internal combustion engines powered by oil are sadly being used.
The Oldsky Planetary Protection Office on Mellanus intends to phase out fossil fuel engines as soon as the planet is capable of producing its own high-energy-density batteries… whenever that is…
also, between you and me, they really ought to get more aquatics flying on these missions.
what an aquatic astronaut could find on Oldsky might be quite shocking.
Anyway outside of the Omen system and Oldsky
Glerbuh has had its fair share of robotic exploration and crewed expeditions.
Two of the four ice giants have also been visited by robotic flyby probes, and Glarpi (the innermost ice giant) has had a robotic orbiter.
The big crewed grand tour expedition to explore all four ice giants and there moons was one of the major science goals of the 2380s outside of exploring and developing Oldsky. However, it had to be modified to turn into a rescue mission for a mellanoid starfleet officer who was stranded on a planet orbiting a nearby star called TE-92. It's a whole thing. If they manage to rescue them maybe they'll write a novel about it.
#long post#mellanoid slime#mellanoid space program#mellanoid slime worm#mellanoid worldbuilding#spaceflight#althist#spaceflight timeline
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Ablation Technology Market worth $8.1 Billion by 2026 - Exclusive Report by MarketsandMarkets™
Ablation Technology Market worth $8.1 Billion by 2026 – Exclusive Report by MarketsandMarkets™
The ablation technology market is projected to reach USD 8.1 Billion by 2026 from USD 5.2 Billion in 2021, at a CAGR of 9.3% during the forecast period, according to a new report by MarketsandMarkets™. The growing elderly population has also driven the incidence of target conditions and contributed to the demand for effective treatment. However, the reuse and reprocessing of devices in developed…
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Before anything else—I don’t know if you will see this but I want to thank everyone who left the kindest and most supportive messages and replies. Thank you sincerely from the bottom of my heart.
To @rainedamodred and @bestbuddybobby — I wouldn’t have made it through without you both.
Now…
I’ve been contemplating what to write here for the last twelve hours.
When I say the past two weeks have been the most difficult in my entire life, that is not an exaggeration. It’s been…hell, honestly.
My husband was diagnosed with an arrhythmia over two years ago. Didn’t sound good but it wasn’t uncommon, but he was a special case, as we were told because on top of being unnaturally tall for our people, he apparently also had an unnaturally large heart…literally. We were presented with options that we were told we could delay due to the pandemic and our concerns regarding safety in authorizing a rather complicated operation during what felt like a perilous time…
The pandemic didn’t really end but it eased. We went in for a checkup. They said it was okay so far as long as he wasn’t feeling any different. He said he was fine. I believed him.
So we thought we had time. We thought this year we could get back on track after the hellacious last couple of years. Get back to what passed for normal, start traveling again, see old friends, revisit our favorite places, hit up our old haunts…
We scheduled him for surgery the beginning of next year…but I suppose fate had other plans.
My husband flatlined twice in the last couple of weeks. He was brought back both times but not without cost. They tried different medications. There were heavy discussions on what options were available. The idea of a heart transplant was offered but waiting for a new heart meant…well, you have some idea, yes? There was no way he could travel for treatment. His heart was going insane…hitting over 200 beats per minute, erratically bouncing from 90 to 145 in a blink…it was a mess.
I coped by not coping…I ended up breaking so many things in our home…a table, a glass wall and whatever I could get my hands on. The floors looked like they were littered with glittering diamonds by the time I was through…so much glass everywhere. It was the only way I could pull myself back together and return to the hospital without falling apart and screaming at someone.
And the goddamn crying…it came and went and I kept waiting to run out of tears but I never did.
I had my mothers and aunts calling from all over in different timezones and at first, I answered but then I would cry more because they cared and they kept offering…kindness and comfort. They wanted to come and be there but I couldn’t imagine keeping up a facade to yet another group of people when I’m busy trying not to fall apart and be The Wife.
And listening to them trying to give me comfort…somehow that was enough to trigger disgusting crying jags that helped nobody and just made a mess out of me. I stopped taking calls. I couldn’t keep my shit together when I kept falling apart at the sound of a caring voice.
For the first time in almost ten years, I was alone. In all the time I’ve been with my husband, I have never been alone…that broke something inside me.
He’s the calm voice, he’s the adult in the room, he makes the decisions, he is the one person that can talk me down from whatever insane cliff I’ve driven myself to…and suddenly, there was just silence.
It reached a point where I was the only one left to make decisions because he couldn’t anymore…his doctors all agreed the best option was to perform a cardiac ablation and implant a device that would be connected to his heart—a defibrillator with a pacemaker backing.
At that point, I was too exhausted mentally, emotionally and psychologically…I said yes to whatever they felt was best. They let me pick and choose off a menu which piece of technology to put next to his heart like I was in an Apple launch event. It was all so…fucking surreal.
Wasn’t it only a few days ago we were celebrating his birthday? He’s only fucking forty-one.
Between the harsh reality that I might lose my husband and the unrelenting conflicts that kept intruding upon an already terrible situation by way of his family…I was barely keeping myself together. I couldn’t even go home anymore and break things…I was that close to breaking things in the hospital but then how would that look if word got out?
I was too scared to go home…too scared I’ll leave and he would slip away.
It’s just the kind of thing he would do…leave without telling because he thinks that would hurt me less. Fuck, sometimes he’s also a dumbass but he is my dumbass, okay?
After I was able to make a decision that would alter his life while hopefully saving it…within twenty-four hours, the device was flown in as well as the specialist that would perform the surgery. Almost two weeks of agony and suddenly, an OR was booked, the doctors were lining up and introducing themselves, discussing their roles in the operation, explaining how it was all going to go down, the technician was making a presentation on how the device would save him on a daily basis while I was too punch drunk to process the information, the anesthesiologist was talking about how they expected things to go, critical care was throwing in his two cents, the cardiologist was trying to reassure me that he would be okay within twenty-four hours after the procedure and he will be able to go home just like that…
It happened so fast, it left my head spinning.
He’s home now. It’s not a fun experience and recovery will take time, but he’s alive and that’s really all that fucking matters.
Right now, I’m dealing with residual bullshit with his family…his sister who is a neurotic passive aggressive piece of work and his mother who seems to have no problem showing him how much she hates him right now…his father continues to be the kindest of them.
I loved and adored these people last month.
One of my aunts said I should not stew in my anger and hold resentment in my heart…that I should give all my negative feelings to God and ask Him to help me continue to love and honor them as I have been doing from the beginning. Ask God to help me keep my love for them so I will not be clouded and remember they are my family…
I told her to call me again next week and try again.
Right now, I just want to get my house back in order and help my husband with his recovery. Get our lives back to where it should be. Find some kind of normal that works for this new us.
I’m trying to channel my rage into more useful outlets outside of that and do something good because that seems like a much better idea than giving in to the urge to commit arson. I am trying so hard not to acknowledge the rage that I am not quite ready to let go of…
I stopped breaking things—I think I’m on the right track.
I keep reminding myself…
He’s alive. He’s not dead. He’s here. He’s breathing. He’s alive. He’s speaking. He’s right here. He’s alive. He’s here. He’s right here.
He’s alive.
And the silence has gone.
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So thanks to my absolute wreck of a menstrual cycle, I got to have an endometrial ablation this morning. Modern medical technology is awesome. I can't say it'll fix the pain, but hopefully the bleeding will be better. I'd still be totally happy to have a hysterectomy, though. Stress increases pain in that area so damn bad.
For now, I'm home, laid up in bed with my pile of plushies. I'm glad this procedure is over and done with. Once I get some rest, I'll slowly wander my way downstairs and get more food. Cramps make it hard to eat much, of course.
Shit, I still don't know how long I need to wait before I can roast the rest of the garlic bulbs. Garlic is a comfort food. And I know what's going to happen as soon as I clean my glass loaf pan. Unless I can be convinced to make sweet bread or something first.
-Era 🗝️😻
#menstrual period#menstruation#menstrual cramps#menstrual cycle#period cramps#comfort food#garlic#i love garlic#personal shit
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“Having mused on clean bodily fluids, HIV and “panic sex,” [The Krokers] suggested: “If, today, there can be such an intense fascination with the fate of the body, might this not be because the body no longer exists?”
They said the body’s functions had been tendered out: computers had taken over the role of memory; test tubes had alienated the womb; the Sony Walkman was a set of “ablated ears”; CGI had replaced perspective; body scanners had taken over from the nervous system.
Maybe Tennant and Lowe don’t see this as a problem.
In the end, the body betrays us, holds us prisoner as it ages and decays. So perhaps ‘Young Offender’ shares the corporeal paranoia we encountered in ‘Dreaming of the Queen’ and ‘To Speak Is A Sin’. “The song, after all, is about an age gap – about whether Tennant can get away with hitting on a twenty year-old. That, rather than any implied heterosexuality, is the reason the boy is inaccessible this time round.”
Excerpt from Chapter 4, ‘Young Offender’ and ‘Liberation’: Technology, Lust and Abstraction. Smile If You Dare: Politics and Pointy Hats with the Pet Shop Boys by Ramzy Alwakeel.
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Instrument from the University of Bern flies to the Moon
As the second man to step out of the lunar module on July 21st, 1969, the first thing that Buzz Aldrin did was to unfurl the Bernese solar wind sail and plant it into the ground on the Moon. This Solar Wind Composition (SWC) experiment, which was planned, built, and analyzed by Professor Johannes Geiss and his team from the Physics Institute at the University of Bern, was the first great highlight in the history of Bernese space exploration.
LIMS (Laser Ablations Ionization Mass Spectrometer), another instrument designed at the University of Bern, is to fly to the Moon with NASA as early as 2027, this time as part of a future NASA CLPS lunar delivery. The funding for LIMS is awarded by the European Space Agency’s ESA in the frame of the PRODEX programme (see infobox below). NASA is working with several American companies to deliver science and technology payloads to the lunar surface through the agency’s CLPS initiative. Peter Wurz, Professor for Astrophysics at the University of Bern and Project Leader for LIMS, explains: “We are very proud to be involved in NASA’s CLPS initiative and that our mass spectrometer is going to be used for the chemical study of lunar rocks.”
A highly sensitive instrument for measurements on the lunar surface
LIMS is a powerful instrument for the examination of a wide variety of samples which meets scientific lunar objectives. Andreas Riedo, Senior Project Manager for LIMS at the Space Research and Planetary Sciences WP Division of the Physics Institute, explains: “LIMS uses a pulsed laser system. The laser pulses are focused through the instrument and directed at a sample of scientific interest that we want to study.” With each laser pulse, a small layer of the sample is detached, and some of the detached material becomes positively charged. “These positively charged particles are sent back into the system, where the chemical composition is measured. This means that we measure the chemical elements and their isotopes, which then enable us, among others, to understand the chemical and physical processes on the Moon,” continues Andreas Riedo.
LIMS is to be installed on a CLPS vendor lunar lander platform, which will house a variety of instruments for lunar exploration and technology demonstrations. The CLPS delivery landing in the southern polar region of the Moon will allow LIMS to take stationary measurements on site. Andreas Riedo explains: “This region is particularly interesting, as it contains certain elements whose isotopes allow us to determine the age of the material and therefore date the timing of geological processes. This makes it possible for us to gather a considerable amount of information on the ground that could otherwise only have been generated in laboratories on Earth.”
Andreas Riedo adds: “In addition, no one before us has ever used this measurement technology on a space mission. Not only will we be the first, but we will also obtain a considerable amount of technical information about our system. This will allow us to optimize the system for other scientific questions and other missions; this is similar to what we’ve already done with the Solar Wind experiment at the University of Bern, which could be used both on the Apollo missions and to measure local interstellar gas.” As Andreas Riedo points out, in the long term, the LIMS instrument could also be considered for its application on future space exploration missions devoted to life detection, for example within the Venus atmosphere, on Mars, and the icy moons of Jupiter and Saturn.
A close collaboration with industry
In the laboratories of the Space Research and Planetary Sciences WP Division at the Physics Institute at the University of Bern, instruments for space missions have been developed and built in the in-house workshops for several decades, including LIMS. “In this area, we work closely with local industry. We will put a LIMS system that has been ‘made in Switzerland’ on the Moon. The development of LIMS began more than 20 years ago, and it is nice to be able to reap the fruits of several years of its effective use,” explains Peter Wurz. Andreas Riedo concludes: “And it goes without saying that this is an area in which we always benefit from the many years of experience and expertise of the University of Bern in instrument design.”
Funding by the SERI / Swiss Space Office
The Swiss federal government participates in the development of scientific instruments and partial systems as part of the PRODEX program (PROgramme de Développement d’EXpériences scientifiques) of the European Space Agency ESA. National contributions to science missions can be developed and built by project teams from research and industry through this program. This transfer of knowledge and technology between science and industry ultimately also gives Switzerland a structural competitive advantage as a business location, and it enables technologies, processes, and products to flow into other markets thus generating added value for our economy.
Bern’s space exploration: with the world’s elite since the first Moon landing
As the second man to step out of the lunar module on July 21st, 1969, the first thing that Buzz Aldrin did was to unfurl the Bernese solar wind sail and plant it into the ground on the Moon. This Solar Wind Composition (SWC) experiment, which was planned, built, and analyzed by Prof. Dr. Johannes Geiss and his team from the Physics Institute at the University of Bern, was the first great highlight in the history of Bernese space exploration.
Bernese space exploration has been working with the world’s elite ever since: The University of Bern regularly participates in space missions of major space organizations, such as ESA, NASA and JAXA. With CHEOPS, the University of Bern shares responsibility with the ESA for an entire mission. Moreover, the Bernese researchers are among the world leaders when it comes to models and calculations on the formation and development of planets.
The successful work of the Space Research and Planetary Sciences (WP) Division at the Physics Institute at the University of Bern has been strengthened by the foundation of a university center of excellence, the Center for Space and Habitability (CSH). The Swiss National Science Foundation also awarded the University of Bern the National Center of Competence in Research (NCCR) PlanetS, which it manages together with the University of Geneva.
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