Frequently Asked Questions About Earthquake Safety & Power Outage Survival: Essential Tips for Extended Blackouts & Why Power Outage Preparedness is Critical for Family Safety & Understanding Different Types of Power Outages & Essential Supplies for Extended Power Outages & Step-by-Step Power Outage Preparation & Temperature Management Without Power & Generator Safety and Operation & Communication During Power Outages & Common Power Outage Mistakes to Avoid & Special Considerations for Medical Needs

Can animals predict earthquakes?

While anecdotal reports describe unusual animal behavior before earthquakes, no reliable prediction method exists. Some animals may sense P-waves seconds before humans feel shaking, but this provides no practical warning time. Japan extensively studied animal behavior for prediction without success. Rather than watching pets for signs, focus on proven preparation methods. When reliable prediction develops, prepared families will benefit most.

Should I buy earthquake insurance?

Standard homeowners insurance excludes earthquake damage, making separate coverage essential in seismic areas. Deductibles typically run 10-20% of coverage amount. Premiums vary dramatically based on location, construction type, and retrofitting. Older homes cost more to insure. Consider your risk tolerance and financial ability to rebuild without insurance. Many discover too late they're financially ruined without coverage. Evaluate costs versus catastrophic loss potential.

Is it safe to be in a doorway during an earthquake?

This outdated advice originated when door frames were strongest home elements. Modern construction makes doorways no safer than other locations while exposing you to swinging doors and lack of overhead protection. Drop, cover, and hold under sturdy furniture provides superior protection. Doorways offer no advantage and several disadvantages. Update your earthquake response knowledge beyond this persistent myth.

How long should I wait before entering my home after an earthquake?

Wait for shaking to completely stop including aftershocks before entering any building. Visually inspect for obvious damage: cracks, separation, or shifting. If uncertain about structural integrity, wait for professional inspection. Yellow-tagged buildings allow brief entry for essentials. Never enter red-tagged buildings regardless of possessions inside. Your life matters more than any belongings. When safe to enter, wear protective equipment and remain alert for hazards.

What causes most earthquake injuries?

Non-structural hazards cause most injuries: falling objects, broken glass, toppling furniture, and swinging fixtures. Building collapse, while dramatic, accounts for relatively few injuries in modern construction. Most injuries are preventable through proper securing of contents. This explains why identical earthquakes cause vastly different casualty rates in prepared versus unprepared regions. Focus preparation on preventing common injuries rather than unlikely building collapse.

Should I turn off gas after every earthquake?

Only shut off gas if you smell gas, hear hissing, or see damage to gas appliances or lines. Unnecessary shut-offs create restoration delays as utility workers must visit each property. However, if shut-off is needed, do it immediately and evacuate. Never turn gas back on yourself - only utility workers should restore service after safety checks. Keep wrenches attached to meters for quick access.

How do I prepare for earthquakes in non-traditional housing?

Mobile homes require earthquake bracing systems preventing shifting off foundations. RVs need wheel chocks and stabilizing jacks. Houseboats must have secure mooring and emergency rafts. High-rise apartments focus on securing contents and knowing evacuation routes. Each housing type has specific vulnerabilities requiring targeted preparation. Consult manufacturers or housing-specific earthquake guides for detailed recommendations.

What about earthquake apps and early warning systems?

Earthquake early warning apps like ShakeAlert provide seconds to tens of seconds warning before shaking arrives. This allows automated responses like stopping trains and opening fire station doors. For individuals, even seconds enable taking cover. Download official apps for your region. Understand limitations - nearby quakes provide minimal warning. Use technology to enhance, not replace, thorough preparation.

How do I help children cope with earthquake fears?

Address fears honestly while emphasizing safety through preparation. Practice drills as games building confidence. Read age-appropriate books explaining earthquakes scientifically. Let children help with preparations giving them control. Maintain routines providing stability. Watch for behavioral changes indicating ongoing anxiety. Seek professional help for persistent fears. Most children handle earthquakes remarkably well when properly prepared and supported.

Is earthquake preparedness worth it in moderate-risk areas?

Absolutely. "Moderate" risk still means potential for damaging earthquakes. The New Madrid earthquakes of 1811-1812 devastated the central US. Charleston's 1886 earthquake killed 60 people. Boston, New York, and Washington D.C. all face earthquake risks. Preparation costs little relative to potential losses. Basic securing of contents and emergency supplies benefits any disaster. Even low-probability events deserve reasonable preparation given catastrophic potential consequences.

On August 14, 2003, David Chen was riding the elevator to his 42nd-floor Manhattan office when everything went dark. The elevator lurched to a stop between floors, emergency lighting failed, and the temperature began rising immediately. For the next four hours, David and six strangers sat in pitch darkness, rationing a single bottle of water while the elevator car turned into a sweltering box. "We had no idea it was the largest blackout in North American history," he later recalled. "We thought it was just our building. Nobody had working phones, we couldn't call for help, and the emergency button did nothing. When they finally got us out, we learned 50 million people had lost power." The 2003 Northeast Blackout revealed how utterly dependent modern life has become on electricity and how quickly civilization's comforts vanish when the power fails. While David's elevator experience was harrowing, it was just the beginning - many areas remained without power for days, forcing families to survive without air conditioning during a heat wave, with no refrigeration, communication, or basic services.

Modern society's complete dependence on electricity creates cascading failures when power systems collapse. Within minutes of an outage, traffic signals fail, causing gridlock and accidents. Elevators trap occupants. Security systems deactivate. Cell towers exhaust battery backups within 4-8 hours. Water pumping stations fail, cutting off supply or reducing pressure. Sewage treatment plants release raw waste. Gas stations can't pump fuel. ATMs and credit card systems stop functioning. Grocery stores close as registers and refrigeration fail. The intricate web of infrastructure we take for granted unravels rapidly without electricity.

Power outages strike far more frequently than most realize, affecting every American family multiple times yearly. While brief outages cause mere inconvenience, extended blackouts lasting days or weeks transform into survival situations. Aging infrastructure struggles with increasing demand - the American Society of Civil Engineers grades U.S. electrical infrastructure at D+. Severe weather causes 70% of outages, with climate change driving more extreme events. Cyberattacks on power grids represent growing threats. Equipment failures, vehicle accidents, and wildlife contacts cause thousands of localized outages annually.

The hidden dangers of power loss extend beyond obvious inconveniences. Food spoilage begins within 4 hours in unopened refrigerators, leading to foodborne illness. Medical equipment failures threaten lives - oxygen concentrators, CPAP machines, medication refrigeration, and dialysis equipment. Carbon monoxide poisoning from improper generator use kills more people than the triggering disasters. Heat-related illness during summer outages and hypothermia during winter events claim vulnerable populations. Structure fires spike from candle use and improper heating attempts. Crime increases in darkened neighborhoods.

Financial impacts accumulate quickly during extended outages. Spoiled food losses average $200-400 per household. Hotel costs for those seeking power reach $100+ nightly. Restaurant meals replace home cooking at premium prices. Lost wages from business closures compound expenses. Medical costs from preventable illnesses and injuries. Generator fuel costs $50-100 daily for continuous operation. Many discover insurance excludes power outage losses unless caused by covered perils. These expenses devastate family budgets already strained by regular bills.

Psychological effects of extended blackouts prove more challenging than physical hardships for many families. The sudden loss of entertainment, communication, and climate control creates stress and anxiety. Children struggle without familiar routines and electronic distractions. Sleep disruption from heat, cold, or security concerns affects everyone's coping ability. Isolation from news and loved ones fuels worry. The uncertainty of restoration timelines prevents proper planning. Families unprepared for "life unplugged" often experience significant conflict and emotional distress during extended outages.

Rolling blackouts represent controlled, temporary power cuts implemented by utilities to prevent total grid collapse during extreme demand. These typically last 1-2 hours per area, rotating through regions to share the burden. While disruptive, advance notice usually allows minimal preparation. California residents experience these during heat waves when air conditioning demand exceeds generation capacity. Understanding your utility's rotation schedule helps plan activities around predictable outages. These controlled events, while frustrating, prevent more catastrophic uncontrolled failures.

Weather-related outages vary dramatically in scope and duration based on the triggering event. Lightning strikes cause brief, localized outages lasting minutes to hours. Ice storms create widespread, extended blackouts as weighted lines snap and trees fall - the 1998 Quebec ice storm left millions without power for weeks in winter. Hurricanes combine wind damage with flooding, destroying infrastructure requiring complete rebuilding. Tornadoes create narrow but devastating damage paths. Heat waves strain systems to failure. Each weather type requires specific preparation strategies.

Infrastructure failures result from equipment age, poor maintenance, or cascading system collapses. Transformer explosions affect neighborhoods for hours or days. Transmission line failures can black out entire regions. The 2003 Northeast blackout began with tree contact on one line but cascaded across eight states. Substation equipment failures require specialized parts potentially taking weeks to obtain. Underground cable failures in urban areas prove particularly challenging to locate and repair. These unpredictable events highlight the importance of constant readiness.

Cyberattacks and physical attacks on power infrastructure represent emerging threats with potentially catastrophic impacts. The 2015 Ukraine power grid cyberattack demonstrated vulnerability, leaving 230,000 without power. Physical attacks on substations using firearms have increased dramatically. Electromagnetic pulse (EMP) events, whether natural from solar storms or human-caused, could disable electronics across continents. While less likely than weather-related outages, these scenarios could create extended blackouts lasting months, requiring serious preparation consideration.

Planned maintenance outages allow utilities to upgrade equipment and prevent failures but still disrupt daily life. These typically last 4-8 hours with advance notice allowing preparation. However, complications can extend planned work significantly. Rural areas may experience longer planned outages due to crew travel times. Understanding your utility's maintenance schedule and notification methods ensures you're not caught unprepared. Sign up for outage alerts and follow utility social media for real-time updates.

Lighting solutions must address both immediate and extended needs safely. LED flashlights provide bright, efficient illumination - include one per family member plus extras. Headlamps free hands for tasks. Battery-powered lanterns light entire rooms safely. Glow sticks offer emergency lighting without fire risk. Solar lights charged during daytime provide overnight illumination. Avoid candles which cause numerous fires during outages. Stock batteries in various sizes, storing separately to prevent corrosion. Consider rechargeable batteries with solar chargers for extended events.

Alternative power sources range from simple battery banks to whole-house generators. Portable battery banks keep phones and small devices charged for days. Solar panels with battery storage provide renewable power for essential devices. Portable generators offer more capacity but require safe operation knowledge and fuel supplies. Inverters connect to car batteries providing temporary household power. Whole-house standby generators automatically restore power but cost thousands installed. Match power solutions to your specific needs, budget, and storage capabilities.

Food preservation without refrigeration becomes critical within hours. Consume refrigerated items first while still safe. Freezers maintain temperature 24-48 hours if unopened and full. Block ice lasts longer than cubes. Dry ice extends freezing but requires careful handling. Coolers with ice preserve essentials temporarily. Focus meal planning on shelf-stable items requiring no refrigeration. Can goods, dried foods, and energy bars sustain families without cooking. Manual can openers are essential. Consider freeze-dried camping meals requiring only water.

Water access may fail during extended outages as pumping stations exhaust backup power. Store minimum one gallon per person daily for at least one week. Fill bathtubs and sinks before outages for sanitation water. Water purification tablets or filters ensure safety if regular supplies fail. Know how to access water heaters safely - they contain 30-80 gallons. Collect rainwater for non-drinking uses. Baby wipes and hand sanitizer reduce water needs for hygiene. Plan assumes normal consumption may double during stress.

Communication equipment maintains critical connections when normal channels fail. Battery-powered or hand-crank radios receive emergency broadcasts and news updates. Two-way radios enable local communication between family members. Cell phone car chargers work when towers function. Portable battery banks extend device life significantly. Solar chargers provide renewable power slowly. Consider amateur radio for serious communication backup. Pre-write important numbers on paper as backup. Whistle signals work when voices fail across distances.

Immediate response (first 5 minutes) sets the tone for successful outage management. Check whether outage affects just your home or the neighborhood - look for streetlights or neighbor's lights. If isolated to your home, check circuit breakers before calling utility. Report outages through utility apps or phone numbers. Unplug sensitive electronics preventing surge damage when power returns. Leave one light switched on to signal restoration. Gather family members and implement your outage plan. Quick, calm response prevents panic and poor decisions.

First hour priorities focus on safety and assessment. Locate flashlights and emergency supplies using glow-in-the-dark markers placed during preparation. Check on vulnerable family members ensuring immediate medical needs are met. Assess likely outage duration based on cause - storm damage versus maintenance. Decide whether to shelter in place or relocate. If staying, designate one room as family gathering space to conserve heat/cooling. Begin conservative battery and fuel usage assuming extended duration. Contact out-of-area relatives confirming safety.

Four-hour threshold triggers food safety decisions. Refrigerators maintain safe temperatures about 4 hours unopened. Consume perishables while safe or move to ice-filled coolers. Group refrigerator access to minimize door openings. Freezers last 24-48 hours depending on fullness. Create ice blocks using available containers before freezing fails. Document freezer contents for insurance claims if spoilage occurs. Shift meal planning to shelf-stable foods. This prevents foodborne illness and reduces waste.

Day one adaptations establish sustainable routines for potential extended outages. Implement water conservation measures anticipating supply interruptions. Establish bathroom protocols if sewage pumps failed. Create entertainment schedules reducing boredom and conflict. Set communication check-in times preserving battery power. Modify sleep schedules accommodating temperature extremes and security concerns. Begin rationing critical supplies like batteries and fuel. Monitor news for restoration estimates and emergency resources. Maintain positive attitude modeling resilience for children.

Extended outage management (beyond 72 hours) requires significant lifestyle adjustments. Establish daily routines providing structure and normalcy. Rotate refrigerator/freezer contents to ice sources if available. Implement strict hygiene protocols preventing illness. Create neighborhood support networks sharing resources and security. Consider temporary relocation if conditions deteriorate. Monitor fuel supplies carefully - generators consume 12-20 gallons daily. Address mounting sanitation issues creatively. Manage increasing stress through open communication and patience. Prepare for prolonged recovery even after power returns.

Summer cooling strategies prevent dangerous heat-related illness during power loss. Open windows at night when outside temperatures drop below indoor levels, closing them at dawn to trap cool air. Create cross-ventilation opening windows on opposite sides. Hang wet sheets over windows for evaporative cooling. Stay hydrated drinking water regularly even without thirst. Wear minimal, light-colored, loose clothing. Spend daylight hours in basements where temperatures remain cooler. Battery-powered fans provide air movement extending comfort. Identify public cooling centers before outages strike.

Winter heating requires careful balance between warmth and safety. Close off unused rooms concentrating heat in one space where family gathers. Hang blankets over windows and doorways creating insulation. Wear layers rather than relying on single heavy garments. Exercise generates body heat safely. Share body heat sleeping in common areas. Never use gas stoves, charcoal grills, or generators indoors - carbon monoxide kills silently. Proper ventilation remains critical even when preserving heat. Fireplaces provide heat if wood supplies exist but require chimney maintenance ensuring safety.

Insulation improvements before outages dramatically improve temperature management. Weather stripping around doors and windows prevents drafts. Cellular blinds trap insulating air layers. Draft stoppers under doors block air movement. Plastic film over windows creates double-pane effects cheaply. Rugs on floors provide insulation and comfort. Foam board insulation in attics reduces heat transfer. These improvements benefit year-round while proving invaluable during outages. Small investments in insulation yield significant comfort improvements when power fails.

Sleeping comfortably without climate control requires adaptation and proper equipment. Summer sleeping: use battery fans, damp cloths on pulse points, and minimal bedding. Freeze water bottles before bed creating personal cooling. Hammocks allow air circulation. Winter sleeping: wear hats preventing head heat loss, use sleeping bags rated for temperatures, and share body heat appropriately. Hot water bottles (if water heating possible) provide hours of warmth. Proper sleeping equipment proves essential for health during extended outages.

Recognizing temperature-related medical emergencies saves lives when hospitals may be overwhelmed. Heat exhaustion symptoms: heavy sweating, weakness, nausea, rapid pulse. Heat stroke: high temperature, altered mental state, hot dry skin - immediately life-threatening. Hypothermia indicators: shivering, confusion, slurred speech, drowsiness. Frostbite signs: numbness, white or grayish skin, hard or waxy appearance. Understanding these conditions enables prompt appropriate response. Prevention through proper temperature management remains far preferable to emergency treatment.

Generator selection requires matching capacity to essential needs, not whole-house operation. Calculate running watts for critical items: refrigerator (600W), freezer (500W), lights (200W), phone chargers (50W), medical equipment varies. Starting watts exceed running watts by 2-3 times. A 5,000-watt generator handles essential needs for most families. Inverter generators provide clean power for electronics. Dual-fuel models offer flexibility between gasoline and propane. Consider noise levels - some neighborhoods restrict generator use. Standby generators cost more but provide automatic operation.

Safe generator placement prevents carbon monoxide poisoning - the leading cause of generator-related deaths. Position generators minimum 20 feet from doors, windows, and vents with exhaust directed away from structures. Never operate in garages, basements, crawl spaces, or near air intakes even with doors open. CO gas accumulates quickly reaching lethal levels. Install battery-operated CO detectors inside homes providing early warning. Mark generator placement zones during preparation ensuring family awareness. These rules apply equally to portable generators and construction models.

Proper connections prevent electrocution and equipment damage. Never connect generators directly to home electrical panels without approved transfer switches - backfeeding kills utility workers and neighbors. Use heavy-duty, outdoor-rated extension cords in good condition. Calculate cord capacity for loads preventing overheating and fires. Ground generators properly reducing shock risks. Connect loads directly to generator outlets avoiding daisy-chaining. Turn off main breaker if using transfer switch. Start generators before connecting loads and disconnect before stopping. Following proper procedures prevents tragedies.

Fuel management extends generator operation during prolonged outages. Gasoline degrades quickly - add stabilizer for storage beyond 30 days. Store fuel in approved containers away from living spaces and ignition sources. Never refuel hot generators risking fires. Typical consumption runs 12-20 gallons daily for 5,000-watt units at half load. Propane stores indefinitely but provides less power per gallon. Create fuel rotation schedules using oldest first. Secure fuel storage preventing theft. Plan for fuel shortages during extended regional outages when stations lack power.

Maintenance ensures reliability when generators are needed most. Run generators monthly under load preventing carburetor gumming. Change oil after first 20 hours on new units, then every 50-100 hours. Replace air filters in dusty conditions. Check spark plugs annually. Store with fresh stabilized fuel or run dry. Keep spare parts: spark plugs, air filters, oil, and pull cords. Document maintenance in logbooks. Professional servicing before hurricane season ensures readiness. Neglected generators fail precisely when most needed.

Cell phone conservation extends communication ability when charging options are limited. Reduce screen brightness to minimum usable levels. Enable airplane mode when not actively using. Close unnecessary apps running in background. Turn off WiFi and Bluetooth unless needed. Use text messages rather than voice calls. Limit social media checking to essential updates. Power down completely when sleeping. These measures can extend battery life from hours to days. Keep phones off until designated check-in times for maximum conservation.

Alternative communication methods provide redundancy when cellular networks fail. Battery-powered two-way radios work locally without infrastructure. NOAA weather radios receive official emergency broadcasts. Ham radio operators often provide emergency networks - no license required for listening. CB radios in vehicles enable highway communication. Satellite phones work anywhere but cost significantly. Internet may function through battery backup if cable infrastructure survives. Maintain multiple options as different emergencies affect systems differently.

Information management prevents dangerous misinformation spread during crises. Verify information through multiple sources before believing or sharing. Official emergency management sources provide reliable updates. Local news radio typically maintains generators for broadcasting. Social media spreads both vital information and dangerous rumors equally fast. Create trusted source lists before emergencies. Understand that initial reports often prove incorrect. Avoid spreading unverified information creating panic. Focus on actionable intelligence rather than speculation.

Family communication protocols reduce network congestion while ensuring connection. Establish specific check-in times rather than continuous attempts. Create group texts including all family members and key contacts. Designate one out-of-state contact for information relay. Keep messages brief focusing on safety status and needs. Use code words for common situations saving time. Practice protocols during non-emergencies building habits. Post schedules where all family members can reference. These protocols ensure communication while preserving limited resources.

Neighborhood communication networks multiply resources and security during extended outages. Establish contact trees where each household checks on specific neighbors. Create central message boards using battery-powered bulletin boards. Schedule regular meetings sharing information and resources. Two-way radios enable quick security alerts. Younger residents assist elderly with technology. Share charging resources preventing duplication. Coordinate supply runs reducing individual exposure. These networks proved invaluable during COVID-19 lockdowns and apply equally to power outages.

Opening refrigerators and freezers frequently destroys temperature maintenance. Each opening loses precious cold, accelerating spoilage. Organize contents before outages enabling quick access. Post inventory lists outside avoiding browsing. Group meal access minimizing openings. Use coolers for frequently needed items. A well-stocked freezer maintains temperature 48 hours unopened but only 24 hours with repeated access. This simple discipline saves hundreds in spoiled food while preventing foodborne illness.

Improper lighting choices create fire hazards and waste resources. Candles cause numerous structure fires during every extended outage. Kerosene lanterns produce dangerous fumes indoors. Excessive flashlight use drains batteries needed for extended duration. Gas lanterns consume fuel better saved for cooking. Match lighting to actual needs - not every room needs illumination. LED lights provide best efficiency. Solar lights charged daily provide renewable evening lighting. Reserve chemical lights for emergencies. Safe, efficient lighting extends resources while preventing accidents.

Delayed decision-making wastes critical early response time. Waiting to see if power returns quickly often means missing ice availability at stores. Delaying generator setup means fuel stations may close. Postponing food preservation decisions guarantees spoilage. Hesitating on relocation means hotels fill completely. Each hour of delay reduces options and increases costs. Implement plans immediately upon outage confirmation. Early decisive action preserves maximum options throughout the event. Prepared families act while others debate.

Social isolation during outages creates unnecessary hardship and danger. Many wrongly assume they must handle everything independently. Neighbors pooling resources accomplish more than individuals struggling separately. Elderly residents may need checking but won't ask for help. Children benefit from playing with others reducing stress. Shared meals extend food supplies while building morale. Security improves through coordinated watching. Pride preventing cooperation wastes energy and resources. Community connection provides resilience beyond individual preparation.

Returning to normal too quickly after restoration causes additional problems. Power surges when electricity returns damage unprotected electronics. Refreezing partially thawed food risks illness. Failing to document losses prevents insurance claims. Not restocking supplies leaves families vulnerable to next outage. Ignoring maintenance after generator use ensures future failures. Learn from each experience improving preparation. Conduct family debriefs identifying what worked and what didn't. Use restoration periods preparing for next inevitable outage. Resilience builds through continuous improvement.

Medication refrigeration requires careful planning as many prescriptions need temperature control. Insulin remains stable at room temperature for 28 days but degrades faster in heat. Antibiotics, some heart medications, and biologics require constant refrigeration. Coolers with ice extend storage temporarily. Small refrigerators run efficiently on generators. Medication fridges in vehicles use 12V power. Contact pharmacies immediately about emergency supplies. Document all losses for insurance. Never use medications exposed to temperature extremes without medical consultation. Plan assumes access to refrigeration will fail.

Medical equipment dependency demands comprehensive backup strategies. Oxygen concentrators require significant generator capacity. CPAP machines need battery backups or DC adapters. Dialysis schedules can't be missed - identify centers with generators. Electric wheelchairs need charging solutions. Feeding pumps require power for scheduled nutrition. Create detailed power requirement lists for all equipment. Register with utilities for priority restoration. Maintain manual backups where possible. Contact equipment suppliers about emergency resources. Life-depending equipment requires multiple redundancies.

Home healthcare coordination becomes critical when professional services are disrupted. Visiting nurses may be unable to reach patients. Medical transportation services often suspend during outages. Therapy appointments get cancelled. Wound care supplies need stockpiling. Communication with providers requires planning. Maintain two-week supplies of all consumables. Document care routines for family implementation. Keep printed copies of all medical information. Establish backup care plans with multiple providers. These preparations prevent medical crises during infrastructure failures.

Emergency medical information must remain accessible without power. Paper copies of medication lists, diagnoses, doctor contacts, and insurance information prove invaluable. Medical alert bracelets work without power. USB drives with medical records need reading devices. Cloud storage requires internet access. Photo cards in wallets provide basic information. Refrigerator medical forms become invisible during outages. Create multiple formats ensuring availability. Update regularly as conditions change. Emergency responders need this information when stress impairs memory.

Prescription management during extended outages requires proactive strategies. Maintain 30-day minimum supplies of all medications. Understand mail-order disruptions during disasters. Know which medications allow emergency refills. Identify 24-hour pharmacies with generators. Keep prescriptions from multiple doctors coordinated. Generic alternatives may be more available. Document all medications with photos for easy refills. Insurance may cover early refills before predicted outages. Never ration critical medications without medical guidance. Medication continuity prevents manageable conditions from becoming emergencies.